zotero-db/storage/9S3EJLW2/.zotero-ft-cache

HIGH SCHOOL

Physics
SENIOR CONTRIBUTING AUTHORS
PAUL PETER URONE, CALIFORNIA STATE UNIVERSITY, SACRAMENTO ROGER HINRICHS, STATE UNIVERSITY OF NEW YORK, COLLEGE AT OSWEGO
CONTRIBUTING AUTHORS
FATIH GOZUACIK, PENNSYLVANIA DEPARTMENT OF EDUCATION DENISE PATTISON, EAST CHAMBERS ISD CATHERINE TABOR, NORTHWEST EARLY HIGH SCHOOL

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Contents
Preface 1
CHAPTER 1
What is Physics? ...................................................................................................................5
Introduction 5 1.1 Physics: Definitions and Applications 5 1.2 The Scientific Methods 14 1.3 The Language of Physics: Physical Quantities and Units 18 Key Terms 40 Section Summary 41 Key Equations 41 Chapter Review 41 Test Prep 46
CHAPTER 2
Motion in One Dimension............................................................................................ 53
Introduction 53 2.1 Relative Motion, Distance, and Displacement 54 2.2 Speed and Velocity 62 2.3 Position vs. Time Graphs 67 2.4 Velocity vs. Time Graphs 73 Key Terms 81 Section Summary 81 Key Equations 81 Chapter Review 82 Test Prep 86
CHAPTER 3
Acceleration .......................................................................................................................... 93
Introduction 93 3.1 Acceleration 93 3.2 Representing Acceleration with Equations and Graphs 99 Key Terms 109 Section Summary 109 Key Equations 109 Chapter Review 109 Test Prep 112
CHAPTER 4
Forces and Newton’s Laws of Motion.............................................................. 115
Introduction 115 4.1 Force 116 4.2 Newton's First Law of Motion: Inertia 118

4.3 Newton's Second Law of Motion 4.4 Newton's Third Law of Motion Key Terms 135 Section Summary 135 Key Equations 136 Chapter Review 136 Test Prep 139

122 128

CHAPTER 5
Motion in Two Dimensions....................................................................................... 143
Introduction 143 5.1 Vector Addition and Subtraction: Graphical Methods 144 5.2 Vector Addition and Subtraction: Analytical Methods 153 5.3 Projectile Motion 162 5.4 Inclined Planes 171 5.5 Simple Harmonic Motion 178 Key Terms 185 Section Summary 185 Key Equations 186 Chapter Review 187 Test Prep 191

CHAPTER 6
Circular and Rotational Motion ............................................................................ 197
Introduction 197 6.1 Angle of Rotation and Angular Velocity 198 6.2 Uniform Circular Motion 205 6.3 Rotational Motion 212 Key Terms 220 Section Summary 220 Key Equations 221 Chapter Review 221 Test Prep 223

CHAPTER 7
Newton's Law of Gravitation ................................................................................. 229
Introduction 229 7.1 Kepler's Laws of Planetary Motion 229 7.2 Newton's Law of Universal Gravitation and Einstein's Theory of General Relativity 237 Key Terms 246 Section Summary 246 Key Equations 246 Chapter Review 246 Test Prep 249

CHAPTER 8
Momentum ........................................................................................................................... 253
Introduction 253

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8.1 Linear Momentum, Force, and Impulse 254 8.2 Conservation of Momentum 259 8.3 Elastic and Inelastic Collisions 262 Key Terms 272 Section Summary 272 Key Equations 272 Chapter Review 273 Test Prep 275
CHAPTER 9
Work, Energy, and Simple Machines............................................................... 279
Introduction 279 9.1 Work, Power, and the Work–Energy Theorem 280 9.2 Mechanical Energy and Conservation of Energy 285 9.3 Simple Machines 290 Key Terms 295 Section Summary 295 Key Equations 295 Chapter Review 296 Test Prep 299
CHAPTER 10
Special Relativity ............................................................................................................ 305
Introduction 305 10.1 Postulates of Special Relativity 305 10.2 Consequences of Special Relativity 312 Key Terms 321 Section Summary 321 Key Equations 321 Chapter Review 322 Test Prep 324
CHAPTER 11
Thermal Energy, Heat, and Work ....................................................................... 327
Introduction 327 11.1 Temperature and Thermal Energy 327 11.2 Heat, Specific Heat, and Heat Transfer 332 11.3 Phase Change and Latent Heat 340 Key Terms 348 Section Summary 348 Key Equations 349 Chapter Review 349 Test Prep 351
CHAPTER 12
Thermodynamics............................................................................................................. 355
Introduction 355 12.1 Zeroth Law of Thermodynamics: Thermal Equilibrium 356

12.2 First law of Thermodynamics: Thermal Energy and Work 358 12.3 Second Law of Thermodynamics: Entropy 366 12.4 Applications of Thermodynamics: Heat Engines, Heat Pumps, and Refrigerators 372 Key Terms 378 Section Summary 378 Key Equations 379 Chapter Review 379 Test Prep 383
CHAPTER 13
Waves and Their Properties ................................................................................... 389
Introduction 389 13.1 Types of Waves 390 13.2 Wave Properties: Speed, Amplitude, Frequency, and Period 394 13.3 Wave Interaction: Superposition and Interference 400 Key Terms 406 Section Summary 406 Key Equations 407 Chapter Review 407 Test Prep 409
CHAPTER 14
Sound........................................................................................................................................ 415
Introduction 415 14.1 Speed of Sound, Frequency, and Wavelength 416 14.2 Sound Intensity and Sound Level 423 14.3 Doppler Effect and Sonic Booms 430 14.4 Sound Interference and Resonance 434 Key Terms 443 Section Summary 443 Key Equations 444 Chapter Review 444 Test Prep 448
CHAPTER 15
Light ........................................................................................................................................... 455
Introduction 455 15.1 The Electromagnetic Spectrum 455 15.2 The Behavior of Electromagnetic Radiation 463 Key Terms 469 Section Summary 469 Key Equations 469 Chapter Review 469 Test Prep 472
CHAPTER 16
Mirrors and Lenses......................................................................................................... 477
Introduction 477
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16.1 Reflection 478 16.2 Refraction 487 16.3 Lenses 498 Key Terms 513 Section Summary 513 Key Equations 513 Chapter Review 514 Test Prep 517
CHAPTER 17
Diffraction and Interference.................................................................................. 523
Introduction 523 17.1 Understanding Diffraction and Interference 523 17.2 Applications of Diffraction, Interference, and Coherence 532 Key Terms 542 Section Summary 542 Key Equations 542 Chapter Review 543 Test Prep 545
CHAPTER 18
Static Electricity .............................................................................................................. 549
Introduction 549 18.1 Electrical Charges, Conservation of Charge, and Transfer of Charge 550 18.2 Coulomb's law 562 18.3 Electric Field 567 18.4 Electric Potential 572 18.5 Capacitors and Dielectrics 580 Key Terms 591 Section Summary 591 Key Equations 592 Chapter Review 592 Test Prep 596
CHAPTER 19
Electrical Circuits............................................................................................................ 603
Introduction 603 19.1 Ohm's law 604 19.2 Series Circuits 612 19.3 Parallel Circuits 621 19.4 Electric Power 632 Key Terms 638 Section Summary 638 Key Equations 638 Chapter Review 639 Test Prep 643

CHAPTER 20
Magnetism ............................................................................................................................ 649
Introduction 649 20.1 Magnetic Fields, Field Lines, and Force 650 20.2 Motors, Generators, and Transformers 665 20.3 Electromagnetic Induction 672 Key Terms 681 Section Summary 681 Key Equations 682 Chapter Review 682 Test Prep 684
CHAPTER 21
The Quantum Nature of Light................................................................................ 691
Introduction 691 21.1 Planck and Quantum Nature of Light 692 21.2 Einstein and the Photoelectric Effect 698 21.3 The Dual Nature of Light 704 Key Terms 711 Section Summary 711 Key Equations 711 Chapter Review 712 Test Prep 715
CHAPTER 22
The Atom................................................................................................................................ 721
Introduction 721 22.1 The Structure of the Atom 721 22.2 Nuclear Forces and Radioactivity 734 22.3 Half Life and Radiometric Dating 743 22.4 Nuclear Fission and Fusion 747 22.5 Medical Applications of Radioactivity: Diagnostic Imaging and Radiation 757 Key Terms 763 Section Summary 763 Key Equations 764 Chapter Review 765 Test Prep 767
CHAPTER 23
Particle Physics................................................................................................................ 771
Introduction 771 23.1 The Four Fundamental Forces 772 23.2 Quarks 779 23.3 The Unification of Forces 790 Key Terms 796 Section Summary 797 Chapter Review 797 Test Prep 801
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Appendix A Reference Tables 807 Index 831

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Preface

1

PREFACE

Welcome to Physics, an OpenStax resource. This textbook was written to increase student access to high-quality learning materials, maintaining highest standards of academic rigor at little to no cost.
About OpenStax
OpenStax is a nonprofit based at Rice University, and it’s our mission to improve student access to education. Our first openly licensed college textbook was published in 2012 and our library has since scaled to over 25 books for college and AP® courses used by hundreds of thousands of students. OpenStax Tutor, our low-cost personalized learning tool, is being used in college courses throughout the country. Through our partnerships with philanthropic foundations and our alliance with other educational resource organizations, OpenStax is breaking down the most common barriers to learning and empowering students and instructors to succeed.
About OpenStax resources
Customization
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Instructors also have the option of creating a customized version of their OpenStax book. The custom version can be made available to students in low-cost print or digital form through their campus bookstore. Visit your book page on OpenStax.org for more information.
Art Atrribution in Physics
In Physics, most art contains attribution to its title, creator or rights holder, host platform, and license within the caption. For art that is openly licensed, anyone may reuse the art as long as they provide the same attribution to its original source. Some art has been provided through permissions and should only be used with the attribution or limitations provided in the credit.

Errata
All OpenStax textbooks undergo a rigorous review process. However, like any professional-grade textbook, errors sometimes occur. The good part is, since our books are webbased, we can make updates periodically. If you have a correction to suggest, submit it through our errata reporting tool. We will review your suggestion and make necessary changes.
Format
You can access this textbook for free in web view or PDF through OpenStax.org, and for a low cost in print.
About Physics
This instructional material was initially created through a Texas Education Agency (TEA) initiative to provide highquality open-source instructional materials to districts free of charge. Funds were allocated by the 84th Texas Legislature (2015) for the creation of state-developed, open-source instructional materials with the request that advanced secondary courses supporting the study of science, technology, engineering, and mathematics should be prioritized.
Physics covers the scope and sequence requirements of a typical one-year physics course. The text provides comprehensive coverage of physical concepts, quantitative examples and skills, and interesting applications. High School Physics has been designed to meet and exceed the requirements of the relevant Texas Essential Knowledge and Skills (TEKS (http://ritter.tea.state.tx.us/rules/tac/ chapter112/ch112c.html#112.39) ), while allowing significant flexibility for instructors.
Qualified and experienced Texas faculty were involved throughout the development process, and the textbooks were reviewed extensively to ensure effectiveness and usability in each course. Reviewers considered each resource’s clarity, accuracy, student support, assessment rigor and appropriateness, alignment to TEKS, and overall quality. Their invaluable suggestions provided the basis for continually improved material and helped to certify that the books are ready for use. The writers and reviewers also considered common course issues, effective teaching strategies, and student engagement to provide instructors and students with useful, supportive content and drive effective learning experiences.
Coverage and scope
Physics presents physical laws, research, concepts, and skills in a logical and engaging progression that should be familiar

2

Preface

to most physics faculty. The textbook begins with a general introduction to physics and scientific processes, which is followed by several chapters on motion and Newton’s laws. After mechanics, the students will move through thermodynamics, waves and sound, and light and optics. Electricity and magnetism and nuclear physics complete the textbook.

been developed with universal design in mind to ensure students of all different backgrounds are reached. Content can be accessed through engaging text, informative visuals, hands-on activities, and online simulations. This diversity of learning media presents a wealth of reinforcement opportunities that allow students to review material in a new and fresh way.

• Chapter 1: What Is Physics? • Chapter 2: Motion in One Dimension • Chapter 3: Acceleration • Chapter 4: Forces and Newton’s Laws of Motion • Chapter 5: Motion in Two Dimensions • Chapter 6: Circular and Rotational Motion • Chapter 7: Newton’s Law of Gravitation • Chapter 8: Momentum • Chapter 9: Work, Energy, and Simple Machines • Chapter 10: Special Relativity • Chapter 11: Thermal Energy, Heat, and Work • Chapter 12: Thermodynamics • Chapter 13: Waves and Their Properties • Chapter 14: Sound • Chapter 15: Light • Chapter 16: Mirrors and Lenses • Chapter 17: Diffraction and Interference • Chapter 18: Static Electricity • Chapter 19: Electrical Circuits • Chapter 20: Magnetism • Chapter 21: The Quantum Nature of Light • Chapter 22: The Atom • Chapter 23: Particle Physics
Flexibility
Like any OpenStax content, this textbook can be modified as needed for use by the instructor depending on the needs of the students in the course. Each set of materials created by OpenStax is organized into units and chapters and can be used like a traditional textbook as the entire syllabus for each course. The materials can also be accessed in smaller chunks for more focused use with a single student or an entire class. Instructors are welcome to download and assign the PDF version of the textbook through a learning management system or can use their LMS to link students to specific chapters and sections of the book relevant to the concept being studied. The entire textbook will be available during the fall of 2020 in an editable Google document, and until then instructors are welcome to copy and paste content from the textbook to modify as needed prior to instruction.
Student-centered focus
Physics uses a friendly voice and exciting examples that appeal to a high school audience. The Chapter Openers, for example, include thought-provoking photographs and introductions that connect the content to experiences relevant to student’s lives. The writing in our program has

Features • Snap Labs: Give students the opportunity to experience
physics through hands-on activities. The labs can be completed quickly and rely primarily on readily available materials so that students can do them at home as they read. • Worked Examples: Promote both analytical and conceptual skills. In each example, the scenario/application is first introduced, followed by a description of the strategy used to solve the problem that emphasizes the concepts involved. These are followed by a fully worked mathematical solution and a discussion of the results. • Fun in Physics: Features physics applications in various entertainment industries. • Work in Physics: Students can explore careers in physics as well as other careers that routinely employ physics. • Boundless Physics: Reveal frontiers in physical knowledge and descriptions of cutting-edge discoveries in physics. • Links to Physics: Highlight connections of physics to other disciplines. • Watch Physics: Support student’s understanding of conceptual and computational skills using videos from Khan Academy. • Virtual Physics: Provide inquiry and discovery-based learning by providing a virtual “sandbox” where students can experiment with simulated physics scenarios and equipment using the University of Colorado-developed PhET simulations. • Tips for Success: Offer students advice on how to approach content or problems.
Practice and Assessment • Grasp Checks: Formative assessments that review the
comprehension of concepts and skills addressed through reading features, interactive features, and snap labs. • Practice Problems: Challenge students to apply concepts and skills they have seen in a Worked Example to solve a problem. • Check Your Understanding: Conceptual questions that, together with the practice problems, provide formative assessment on key topics in each section. • Performance Tasks: Challenge students to apply the content and skills they have learned to find a solution to a practical situation. • Test Prep: Helps prepare students to successfully respond to the format and rigor of standardized tests. The test prep includes multiple choice, short answer, and extended

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Preface

3

response items.
Additional resources
Student and instructor resources
We’ve compiled additional resources for both students and instructors, including Getting Started Guides, PowerPoint slides, and an instructor answer guide. Instructor resources require a verified instructor account, which you can apply for when you log in or create your account on OpenStax.org. Take advantage of these resources to supplement your OpenStax book.
Partner resources
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About the Authors
Senior Contributing Authors
Paul Peter Urone, California State University, Sacramento Roger Hinrichs, State University of New York, College at Oswego
Contributing Authors
Fatih Gozuacik (Director of Technology and Education) holds master’s degrees in physics and atomic physics from Texas A&M Commerce and Sakarya University in Turkey. In addition to teaching AP® and College Physics, he has been a mentor for the Physics Bowl and the Science Olympiad, and has served as a college counselor for junior and senior students. Fatih was named the 2015 STEM teacher of the year by Educate Texas.

Denise Pattison (East Chambers ISD) was born and raised in Lumberton, Texas. She graduated from Lamar University Beaumont in 2004 with a degree in science and has taught Physics, Pre AP® Physics, and IPC Physics. She loves teaching because it offers the opportunity to make a difference in a person’s life.
Catherine Tabor (Northwest Early High School) holds Bachelors degrees in Mathematics and Physics, a Master’s degree in Physics, and is working towards a PhD in Computer Science. She has taught for over twenty years, holding positions at a number of high schools in El Paso and colleges including Evergreen State and UT El Paso. At Northwest Early HS, she teaches Astronomy, AP® Physics, and AP® Computer Science.
Reviewers
• Bryan Callow, Lindenwold High School, Lindenwold, NJ • John Boehringer, Prosper High School, Prosper, TX • Wade Green, Stony Point High School, Round Rock, TX • Susan Vogel, Rockwall-Heath High School, Heath TX • Stan Hutto, Southwest Christian School, TX • Richard Lines, Garland High School, Garland, TX • Penny McCool, San Antonio ISD, Raise Up Texas Coach • Loren Lykins, Science Department Chairman—Carlisle
Independent School District, TX • Janie Horn, Cleveland High School, Magnolia, TX • Sean Oshman, Garland Independent School District,
TX • Cort Gillen, Cypress Ranch High School, TX

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Preface

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CHAPTER 1
What is Physics?
Figure 1.1 Galaxies, such as the Andromeda galaxy pictured here, are immense in size. The small blue spots in this photo are also galaxies. The same physical laws apply to objects as large as galaxies or objects as small as atoms. The laws of physics are, therefore, surprisingly few in number. (NASA, JPL-Caltech, P. Barmby, Harvard-Smithsonian Center for Astrophysics).
Chapter Outline
1.1 Physics: Definitions and Applications 1.2 The Scientific Methods 1.3 The Language of Physics: Physical Quantities and Units
INTRODUCTION Take a look at the image above of the Andromeda Galaxy (Figure 1.1), which contains billions of stars. This galaxy is the nearest one to our own galaxy (the Milky Way) but is still a staggering 2.5 million light years from Earth. (A light year is a measurement of the distance light travels in a year.) Yet, the primary force that affects the movement of stars within Andromeda is the same force that we contend with here on Earth—namely, gravity. You may soon realize that physics plays a much larger role in your life than you thought. This section introduces you to the realm of physics, and discusses applications of physics in other disciplines of study. It also describes the methods by which science is done, and how scientists communicate their results to each other.
1.1 Physics: Definitions and Applications
Section Learning Objectives By the end of this section, you will be able to do the following:
• Describe the definition, aims, and branches of physics • Describe and distinguish classical physics from modern physics and describe the importance of relativity,
quantum mechanics, and relativistic quantum mechanics in modern physics • Describe how aspects of physics are used in other sciences (e.g., biology, chemistry, geology, etc.) as well as in
everyday technology

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Chapter 1 • What is Physics?

Section Key Terms

atom

classical physics

modern physics

physics quantum mechanics theory of relativity

What Physics Is
Think about all of the technological devices that you use on a regular basis. Computers, wireless internet, smart phones, tablets, global positioning system (GPS), MP3 players, and satellite radio might come to mind. Next, think about the most exciting modern technologies that you have heard about in the news, such as trains that levitate above their tracks, invisibility cloaks that bend light around them, and microscopic robots that fight diseased cells in our bodies. All of these groundbreaking advancements rely on the principles of physics.
Physics is a branch of science. The word science comes from a Latin word that means having knowledge, and refers the knowledge of how the physical world operates, based on objective evidence determined through observation and experimentation. A key requirement of any scientific explanation of a natural phenomenon is that it must be testable; one must be able to devise and conduct an experimental investigation that either supports or refutes the explanation. It is important to note that some questions fall outside the realm of science precisely because they deal with phenomena that are not scientifically testable. This need for objective evidence helps define the investigative process scientists follow, which will be described later in this chapter.
Physics is the science aimed at describing the fundamental aspects of our universe. This includes what things are in it, what properties of those things are noticeable, and what processes those things or their properties undergo. In simpler terms, physics attempts to describe the basic mechanisms that make our universe behave the way it does. For example, consider a smart phone (Figure 1.2). Physics describes how electric current interacts with the various circuits inside the device. This knowledge helps engineers select the appropriate materials and circuit layout when building the smart phone. Next, consider a GPS. Physics describes the relationship between the speed of an object, the distance over which it travels, and the time it takes to travel that distance. When you use a GPS device in a vehicle, it utilizes these physics relationships to determine the travel time from one location to another.

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1.1 • Physics: Definitions and Applications

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Figure 1.2 Physics describes the way that electric charge flows through the circuits of this device. Engineers use their knowledge of physics to construct a smartphone with features that consumers will enjoy, such as a GPS function. GPS uses physics equations to determine the driving time between two locations on a map. (@gletham GIS, Social, Mobile Tech Images)
As our technology evolved over the centuries, physics expanded into many branches. Ancient peoples could only study things that they could see with the naked eye or otherwise experience without the aid of scientific equipment. This included the study of kinematics, which is the study of moving objects. For example, ancient people often studied the apparent motion of objects in the sky, such as the sun, moon, and stars. This is evident in the construction of prehistoric astronomical observatories, such as Stonehenge in England (shown in Figure 1.3).
Figure 1.3 Stonehenge is a monument located in England that was built between 3000 and 1000 B.C. It functions as an ancient astronomical observatory, with certain rocks in the monument aligning with the position of the sun during the summer and winter solstices. Other rocks align with the rising and setting of the moon during certain days of the year. (Citypeek, Wikimedia Commons)
Ancient people also studied statics and dynamics, which focus on how objects start moving, stop moving, and change speed and direction in response to forces that push or pull on the objects. This early interest in kinematics and dynamics allowed humans to invent simple machines, such as the lever, the pulley, the ramp, and the wheel. These simple machines were gradually

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Chapter 1 • What is Physics?

combined and integrated to produce more complicated machines, such as wagons and cranes. Machines allowed humans to gradually do more work more effectively in less time, allowing them to create larger and more complicated buildings and structures, many of which still exist today from ancient times.
As technology advanced, the branches of physics diversified even more. These include branches such as acoustics, the study of sound, and optics, the study of the light. In 1608, the invention of the telescope by a Germany spectacle maker, Hans Lippershey, led to huge breakthroughs in astronomy—the study of objects or phenomena in space. One year later, in 1609, Galileo Galilei began the first studies of the solar system and the universe using a telescope. During the Renaissance era, Isaac Newton used observations made by Galileo to construct his three laws of motion. These laws were the standard for studying kinematics and dynamics even today.
Another major branch of physics is thermodynamics, which includes the study of thermal energy and the transfer of heat. James Prescott Joule, an English physicist, studied the nature of heat and its relationship to work. Joule’s work helped lay the foundation for the first of three laws of thermodynamics that describe how energy in our universe is transferred from one object to another or transformed from one form to another. Studies in thermodynamics were motivated by the need to make engines more efficient, keep people safe from the elements, and preserve food.
The 18th and 19th centuries also saw great strides in the study of electricity and magnetism. Electricity involves the study of electric charges and their movements. Magnetism had long ago been noticed as an attractive force between a magnetized object and a metal like iron, or between the opposite poles (North and South) of two magnetized objects. In 1820, Danish physicist Hans Christian Oersted showed that electric currents create magnetic fields. In 1831, English inventor Michael Faraday showed that moving a wire through a magnetic field could induce an electric current. These studies led to the inventions of the electric motor and electric generator, which revolutionized human life by bringing electricity and magnetism into our machines.
The end of the 19th century saw the discovery of radioactive substances by the French scientists Marie and Pierre Curie. Nuclear physics involves studying the nuclei of atoms, the source of nuclear radiation. In the 20th century, the study of nuclear physics eventually led to the ability to split the nucleus of an atom, a process called nuclear fission. This process is the basis for nuclear power plants and nuclear weapons. Also, the field of quantum mechanics, which involves the mechanics of atoms and molecules, saw great strides during the 20th century as our understanding of atoms and subatomic particles increased (see below).
Early in the 20th century, Albert Einstein revolutionized several branches of physics, especially relativity. Relativity revolutionized our understanding of motion and the universe in general as described further in this chapter. Now, in the 21st century, physicists continue to study these and many other branches of physics.
By studying the most important topics in physics, you will gain analytical abilities that will enable you to apply physics far beyond the scope of what can be included in a single book. These analytical skills will help you to excel academically, and they will also help you to think critically in any career you choose to pursue.
Physics: Past and Present
The word physics is thought to come from the Greek word phusis, meaning nature. The study of nature later came to be called natural philosophy. From ancient times through the Renaissance, natural philosophy encompassed many fields, including astronomy, biology, chemistry, mathematics, and medicine. Over the last few centuries, the growth of scientific knowledge has resulted in ever-increasing specialization and branching of natural philosophy into separate fields, with physics retaining the most basic facets. Physics, as it developed from the Renaissance to the end of the 19th century, is called classical physics. Revolutionary discoveries starting at the beginning of the 20th century transformed physics from classical physics to modern physics.
Classical physics is not an exact description of the universe, but it is an excellent approximation under the following conditions: (1) matter must be moving at speeds less than about 1 percent of the speed of light, (2) the objects dealt with must be large enough to be seen with the naked eye, and (3) only weak gravity, such as that generated by Earth, can be involved. Very small objects, such as atoms and molecules, cannot be adequately explained by classical physics. These three conditions apply to almost all of everyday experience. As a result, most aspects of classical physics should make sense on an intuitive level.
Many laws of classical physics have been modified during the 20th century, resulting in revolutionary changes in technology, society, and our view of the universe. As a result, many aspects of modern physics, which occur outside of the range of our everyday experience, may seem bizarre or unbelievable. So why is most of this textbook devoted to classical physics? There are

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1.1 • Physics: Definitions and Applications

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two main reasons. The first is that knowledge of classical physics is necessary to understand modern physics. The second reason is that classical physics still gives an accurate description of the universe under a wide range of everyday circumstances.
Modern physics includes two revolutionary theories: relativity and quantum mechanics. These theories deal with the very fast and the very small, respectively. The theory of relativity was developed by Albert Einstein in 1905. By examining how two observers moving relative to each other would see the same phenomena, Einstein devised radical new ideas about time and space. He came to the startling conclusion that the measured length of an object travelling at high speeds (greater than about one percent of the speed of light) is shorter than the same object measured at rest. Perhaps even more bizarre is the idea the time for the same process to occur is different depending on the motion of the observer. Time passes more slowly for an object travelling at high speeds. A trip to the nearest star system, Alpha Centauri, might take an astronaut 4.5 Earth years if the ship travels near the speed of light. However, because time is slowed at higher speeds, the astronaut would age only 0.5 years during the trip. Einstein’s ideas of relativity were accepted after they were confirmed by numerous experiments.
Gravity, the force that holds us to Earth, can also affect time and space. For example, time passes more slowly on Earth’s surface than for objects farther from the surface, such as a satellite in orbit. The very accurate clocks on global positioning satellites have to correct for this. They slowly keep getting ahead of clocks at Earth’s surface. This is called time dilation, and it occurs because gravity, in essence, slows down time.
Large objects, like Earth, have strong enough gravity to distort space. To visualize this idea, think about a bowling ball placed on a trampoline. The bowling ball depresses or curves the surface of the trampoline. If you rolled a marble across the trampoline, it would follow the surface of the trampoline, roll into the depression caused by the bowling ball, and hit the ball. Similarly, the Earth curves space around it in the shape of a funnel. These curves in space due to the Earth cause objects to be attracted to Earth (i.e., gravity).
Because of the way gravity affects space and time, Einstein stated that gravity affects the space-time continuum, as illustrated in Figure 1.4. This is why time proceeds more slowly at Earth’s surface than in orbit. In black holes, whose gravity is hundreds of times that of Earth, time passes so slowly that it would appear to a far-away observer to have stopped!

Figure 1.4 Einstein’s theory of relativity describes space and time as an interweaved mesh. Large objects, such as a planet, distort space, causing objects to fall in toward the planet due to the action of gravity. Large objects also distort time, causing time to proceed at a slower rate near the surface of Earth compared with the area outside of the distorted region of space-time.
In summary, relativity says that in describing the universe, it is important to realize that time, space and speed are not absolute. Instead, they can appear different to different observers. Einstein’s ability to reason out relativity is even more amazing because we cannot see the effects of relativity in our everyday lives.
Quantum mechanics is the second major theory of modern physics. Quantum mechanics deals with the very small, namely, the subatomic particles that make up atoms. Atoms (Figure 1.5) are the smallest units of elements. However, atoms themselves are constructed of even smaller subatomic particles, such as protons, neutrons and electrons. Quantum mechanics strives to

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Chapter 1 • What is Physics?

describe the properties and behavior of these and other subatomic particles. Often, these particles do not behave in the ways expected by classical physics. One reason for this is that they are small enough to travel at great speeds, near the speed of light.

Figure 1.5 Using a scanning tunneling microscope (STM), scientists can see the individual atoms that compose this sheet of gold. (Erwinrossen)
At particle colliders (Figure 1.6), such as the Large Hadron Collider on the France-Swiss border, particle physicists can make subatomic particles travel at very high speeds within a 27 kilometers (17 miles) long superconducting tunnel. They can then study the properties of the particles at high speeds, as well as collide them with each other to see how they exchange energy. This has led to many intriguing discoveries such as the Higgs-Boson particle, which gives matter the property of mass, and antimatter, which causes a huge energy release when it comes in contact with matter.
Figure 1.6 Particle colliders such as the Large Hadron Collider in Switzerland or Fermilab in the United States (pictured here), have long tunnels that allows subatomic particles to be accelerated to near light speed. (Andrius.v )
Physicists are currently trying to unify the two theories of modern physics, relativity and quantum mechanics, into a single, comprehensive theory called relativistic quantum mechanics. Relating the behavior of subatomic particles to gravity, time, and space will allow us to explain how the universe works in a much more comprehensive way.
Application of Physics
You need not be a scientist to use physics. On the contrary, knowledge of physics is useful in everyday situations as well as in nonscientific professions. For example, physics can help you understand why you shouldn’t put metal in the microwave (Figure 1.7), why a black car radiator helps remove heat in a car engine, and why a white roof helps keep the inside of a house cool. The operation of a car’s ignition system, as well as the transmission of electrical signals through our nervous system, are much easier to understand when you think about them in terms of the basic physics of electricity.
Figure 1.7 Why can't you put metal in the microwave? Microwaves are high-energy radiation that increases the movement of electrons in
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1.1 • Physics: Definitions and Applications

11

metal. These moving electrons can create an electrical current, causing sparking that can lead to a fire. (= MoneyBlogNewz)
Physics is the foundation of many important scientific disciplines. For example, chemistry deals with the interactions of atoms and molecules. Not surprisingly, chemistry is rooted in atomic and molecular physics. Most branches of engineering are also applied physics. In architecture, physics is at the heart of determining structural stability, acoustics, heating, lighting, and cooling for buildings. Parts of geology, the study of nonliving parts of Earth, rely heavily on physics; including radioactive dating, earthquake analysis, and heat transfer across Earth’s surface. Indeed, some disciplines, such as biophysics and geophysics, are hybrids of physics and other disciplines.
Physics also describes the chemical processes that power the human body. Physics is involved in medical diagnostics, such as xrays, magnetic resonance imaging (MRI), and ultrasonic blood flow measurements (Figure 1.8). Medical therapy Physics also has many applications in biology, the study of life. For example, physics describes how cells can protect themselves using their cell walls and cell membranes (Figure 1.9). Medical therapy sometimes directly involves physics, such as in using X-rays to diagnose health conditions. Physics can also explain what we perceive with our senses, such as how the ears detect sound or the eye detects color.

Figure 1.8 Magnetic resonance imaging (MRI) uses electromagnetic waves to yield an image of the brain, which doctors can use to find diseased regions. (Rashmi Chawla, Daniel Smith, and Paul E. Marik)
Figure 1.9 Physics, chemistry, and biology help describe the properties of cell walls in plant cells, such as the onion cells seen here. (Umberto Salvagnin)
BOUNDLESS PHYSICS The Physics of Landing on a Comet
On November 12, 2014, the European Space Agency’s Rosetta spacecraft (shown in Figure 1.10) became the first ever to reach and orbit a comet. Shortly after, Rosetta’s rover, Philae, landed on the comet, representing the first time humans have ever landed a space probe on a comet.

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Chapter 1 • What is Physics?

Figure 1.10 The Rosetta spacecraft, with its large and revolutionary solar panels, carried the Philae lander to a comet. The lander then detached and landed on the comet’s surface. (European Space Agency)
After traveling 6.4 billion kilometers starting from its launch on Earth, Rosetta landed on the comet 67P/ChuryumovGerasimenko, which is only 4 kilometers wide. Physics was needed to successfully plot the course to reach such a small, distant, and rapidly moving target. Rosetta’s path to the comet was not straight forward. The probe first had to travel to Mars so that Mars’s gravity could accelerate it and divert it in the exact direction of the comet. This was not the first time humans used gravity to power our spaceships. Voyager 2, a space probe launched in 1977, used the gravity of Saturn to slingshot over to Uranus and Neptune (illustrated in Figure 1.11), providing the first pictures ever taken of these planets. Now, almost 40 years after its launch, Voyager 2 is at the very edge of our solar system and is about to enter interstellar space. Its sister ship, Voyager 1 (illustrated in Figure 1.11), which was also launched in 1977, is already there. To listen to the sounds of interstellar space or see images that have been transmitted back from the Voyager I or to learn more about the Voyager mission, visit the Voyager’s Mission website (https://openstax.org/l/28voyager) .
Figure 1.11 a) Voyager 2, launched in 1977, used the gravity of Saturn to slingshot over to Uranus and Neptune. NASA b) A rendering of Voyager 1, the first space probe to ever leave our solar system and enter interstellar space. NASA
Both Voyagers have electrical power generators based on the decay of radioisotopes. These generators have served them for almost 40 years. Rosetta, on the other hand, is solar-powered. In fact, Rosetta became the first space probe to travel beyond the asteroid belt by relying only on solar cells for power generation. At 800 million kilometers from the sun, Rosetta receives sunlight that is only 4 percent as strong as on Earth. In addition, it is very cold in space. Therefore, a lot of physics went into developing Rosetta’s low-intensity low-temperature solar cells. In this sense, the Rosetta project nicely shows the huge range of topics encompassed by physics: from modeling the movement of gigantic planets over huge distances within our solar systems, to learning how to generate electric power from low-intensity light. Physics is, by far, the broadest field of science.
GRASP CHECK What characteristics of the solar system would have to be known or calculated in order to send a probe to a distant planet, such as Jupiter?
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a. the effects due to the light from the distant stars b. the effects due to the air in the solar system c. the effects due to the gravity from the other planets d. the effects due to the cosmic microwave background radiation

1.1 • Physics: Definitions and Applications

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In summary, physics studies many of the most basic aspects of science. A knowledge of physics is, therefore, necessary to understand all other sciences. This is because physics explains the most basic ways in which our universe works. However, it is not necessary to formally study all applications of physics. A knowledge of the basic laws of physics will be most useful to you, so that you can use them to solve some everyday problems. In this way, the study of physics can improve your problem-solving skills.
Check Your Understanding
1. Which of the following is not an essential feature of scientific explanations? a. They must be subject to testing. b. They strictly pertain to the physical world. c. Their validity is judged based on objective observations. d. Once supported by observation, they can be viewed as a fact.
2. Which of the following does not represent a question that can be answered by science? a. How much energy is released in a given nuclear chain reaction? b. Can a nuclear chain reaction be controlled? c. Should uncontrolled nuclear reactions be used for military applications? d. What is the half-life of a waste product of a nuclear reaction?
3. What are the three conditions under which classical physics provides an excellent description of our universe? a. 1. Matter is moving at speeds less than about 1 percent of the speed of light 2. Objects dealt with must be large enough to be seen with the naked eye. 3. Strong electromagnetic fields are involved.
b. 1. Matter is moving at speeds less than about 1 percent of the speed of light. 2. Objects dealt with must be large enough to be seen with the naked eye. 3. Only weak gravitational fields are involved.
c. 1. Matter is moving at great speeds, comparable to the speed of light. 2. Objects dealt with are large enough to be seen with the naked eye. 3. Strong gravitational fields are involved.
d. 1. Matter is moving at great speeds, comparable to the speed of light. 2. Objects are just large enough to be visible through the most powerful telescope. 3. Only weak gravitational fields are involved.
4. Why is the Greek word for nature appropriate in describing the field of physics? a. Physics is a natural science that studies life and living organism on habitable planets like Earth. b. Physics is a natural science that studies the laws and principles of our universe. c. Physics is a physical science that studies the composition, structure, and changes of matter in our universe. d. Physics is a social science that studies the social behavior of living beings on habitable planets like Earth.
5. Which aspect of the universe is studied by quantum mechanics? a. objects at the galactic level b. objects at the classical level c. objects at the subatomic level d. objects at all levels, from subatomic to galactic

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Chapter 1 • What is Physics?

1.2 The Scientific Methods
Section Learning Objectives By the end of this section, you will be able to do the following:
• Explain how the methods of science are used to make scientific discoveries • Define a scientific model and describe examples of physical and mathematical models used in physics • Compare and contrast hypothesis, theory, and law
Section Key Terms

experiment

hypothesis

model observation principle

scientific law scientific methods theory universal

Scientific Methods
Scientists often plan and carry out investigations to answer questions about the universe around us. Such laws are intrinsic to the universe, meaning that humans did not create them and cannot change them. We can only discover and understand them. Their discovery is a very human endeavor, with all the elements of mystery, imagination, struggle, triumph, and disappointment inherent in any creative effort. The cornerstone of discovering natural laws is observation. Science must describe the universe as it is, not as we imagine or wish it to be.
We all are curious to some extent. We look around, make generalizations, and try to understand what we see. For example, we look up and wonder whether one type of cloud signals an oncoming storm. As we become serious about exploring nature, we become more organized and formal in collecting and analyzing data. We attempt greater precision, perform controlled experiments (if we can), and write down ideas about how data may be organized. We then formulate models, theories, and laws based on the data we have collected, and communicate those results with others. This, in a nutshell, describes the scientific method that scientists employ to decide scientific issues on the basis of evidence from observation and experiment.
An investigation often begins with a scientist making an observation. The scientist observes a pattern or trend within the natural world. Observation may generate questions that the scientist wishes to answer. Next, the scientist may perform some research about the topic and devise a hypothesis. A hypothesis is a testable statement that describes how something in the natural world works. In essence, a hypothesis is an educated guess that explains something about an observation.
Scientists may test the hypothesis by performing an experiment. During an experiment, the scientist collects data that will help them learn about the phenomenon they are studying. Then the scientists analyze the results of the experiment (that is, the data), often using statistical, mathematical, and/or graphical methods. From the data analysis, they draw conclusions. They may conclude that their experiment either supports or rejects their hypothesis. If the hypothesis is supported, the scientist usually goes on to test another hypothesis related to the first. If their hypothesis is rejected, they will often then test a new and different hypothesis in their effort to learn more about whatever they are studying.
Scientific processes can be applied to many situations. Let’s say that you try to turn on your car, but it will not start. You have just made an observation! You ask yourself, "Why won’t my car start?" You can now use scientific processes to answer this question. First, you generate a hypothesis such as, "The car won’t start because it has no gasoline in the gas tank." To test this hypothesis, you put gasoline in the car and try to start it again. If the car starts, then your hypothesis is supported by the experiment. If the car does not start, then your hypothesis is rejected. You will then need to think up a new hypothesis to test such as, "My car won’t start because the fuel pump is broken." Hopefully, your investigations lead you to discover why the car won’t start and enable you to fix it.
Modeling
A model is a representation of something that is often too difficult (or impossible) to study directly. Models can take the form of physical models, equations, computer programs, or simulations—computer graphics/animations. Models are tools that are especially useful in modern physics because they let us visualize phenomena that we normally cannot observe with our senses, such as very small objects or objects that move at high speeds. For example, we can understand the structure of an atom using models, despite the fact that no one has ever seen an atom with their own eyes. Models are always approximate, so they are simpler to consider than the real situation; the more complete a model is, the more complicated it must be. Models put the

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1.2 • The Scientific Methods

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intangible or the extremely complex into human terms that we can visualize, discuss, and hypothesize about.
Scientific models are constructed based on the results of previous experiments. Even still, models often only describe a phenomenon partially or in a few limited situations. Some phenomena are so complex that they may be impossible to model them in their entirety, even using computers. An example is the electron cloud model of the atom in which electrons are moving around the atom’s center in distinct clouds (Figure 1.12), that represent the likelihood of finding an electron in different places. This model helps us to visualize the structure of an atom. However, it does not show us exactly where an electron will be within its cloud at any one particular time.

Figure 1.12 The electron cloud model of the atom predicts the geometry and shape of areas where different electrons may be found in an atom. However, it cannot indicate exactly where an electron will be at any one time.
As mentioned previously, physicists use a variety of models including equations, physical models, computer simulations, etc. For example, three-dimensional models are often commonly used in chemistry and physics to model molecules. Properties other than appearance or location are usually modelled using mathematics, where functions are used to show how these properties relate to one another. Processes such as the formation of a star or the planets, can also be modelled using computer simulations. Once a simulation is correctly programmed based on actual experimental data, the simulation can allow us to view processes that happened in the past or happen too quickly or slowly for us to observe directly. In addition, scientists can also run virtual experiments using computer-based models. In a model of planet formation, for example, the scientist could alter the amount or type of rocks present in space and see how it affects planet formation.
Scientists use models and experimental results to construct explanations of observations or design solutions to problems. For example, one way to make a car more fuel efficient is to reduce the friction or drag caused by air flowing around the moving car. This can be done by designing the body shape of the car to be more aerodynamic, such as by using rounded corners instead of sharp ones. Engineers can then construct physical models of the car body, place them in a wind tunnel, and examine the flow of air around the model. This can also be done mathematically in a computer simulation. The air flow pattern can be analyzed for regions smooth air flow and for eddies that indicate drag. The model of the car body may have to be altered slightly to produce the smoothest pattern of air flow (i.e., the least drag). The pattern with the least drag may be the solution to increasing fuel efficiency of the car. This solution might then be incorporated into the car design.
Snap Lab
Using Models and the Scientific Processes
Be sure to secure loose items before opening the window or door.
In this activity, you will learn about scientific models by making a model of how air flows through your classroom or a room in your house.
• One room with at least one window or door that can be opened • Piece of single-ply tissue paper
1. Work with a group of four, as directed by your teacher. Close all of the windows and doors in the room you are working in. Your teacher may assign you a specific window or door to study.

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Chapter 1 • What is Physics?

2. Before opening any windows or doors, draw a to-scale diagram of your room. First, measure the length and width of your room using the tape measure. Then, transform the measurement using a scale that could fit on your paper, such as 5 centimeters = 1 meter.
3. Your teacher will assign you a specific window or door to study air flow. On your diagram, add arrows showing your hypothesis (before opening any windows or doors) of how air will flow through the room when your assigned window or door is opened. Use pencil so that you can easily make changes to your diagram.
4. On your diagram, mark four locations where you would like to test air flow in your room. To test for airflow, hold a strip of single ply tissue paper between the thumb and index finger. Note the direction that the paper moves when exposed to the airflow. Then, for each location, predict which way the paper will move if your air flow diagram is correct.
5. Now, each member of your group will stand in one of the four selected areas. Each member will test the airflow Agree upon an approximate height at which everyone will hold their papers.
6. When you teacher tells you to, open your assigned window and/or door. Each person should note the direction that their paper points immediately after the window or door was opened. Record your results on your diagram.
7. Did the airflow test data support or refute the hypothetical model of air flow shown in your diagram? Why or why not? Correct your model based on your experimental evidence.
8. With your group, discuss how accurate your model is. What limitations did it have? Write down the limitations that your group agreed upon.
GRASP CHECK
Your diagram is a model, based on experimental evidence, of how air flows through the room. Could you use your model to predict how air would flow through a new window or door placed in a different location in the classroom? Make a new diagram that predicts the room’s airflow with the addition of a new window or door. Add a short explanation that describes how. a. Yes, you could use your model to predict air flow through a new window. The earlier experiment of air flow would
help you model the system more accurately. b. Yes, you could use your model to predict air flow through a new window. The earlier experiment of air flow is not
useful for modeling the new system. c. No, you cannot model a system to predict the air flow through a new window. The earlier experiment of air flow
would help you model the system more accurately. d. No, you cannot model a system to predict the air flow through a new window. The earlier experiment of air flow is
not useful for modeling the new system.

Scientific Laws and Theories
A scientific law is a description of a pattern in nature that is true in all circumstances that have been studied. That is, physical laws are meant to be universal, meaning that they apply throughout the known universe. Laws are often also concise, whereas theories are more complicated. A law can be expressed in the form of a single sentence or mathematical equation. For example, Newton’s second law of motion, which relates the motion of an object to the force applied (F), the mass of the object (m), and the object’s acceleration (a), is simply stated using the equation
Scientific ideas and explanations that are true in many, but not all situations in the universe are usually called principles. An example is Pascal’s principle, which explains properties of liquids, but not solids or gases. However, the distinction between laws and principles is sometimes not carefully made in science. A theory is an explanation for patterns in nature that is supported by much scientific evidence and verified multiple times by multiple researchers. While many people confuse theories with educated guesses or hypotheses, theories have withstood more rigorous testing and verification than hypotheses.
As a closing idea about scientific processes, we want to point out that scientific laws and theories, even those that have been supported by experiments for centuries, can still be changed by new discoveries. This is especially true when new technologies emerge that allow us to observe things that were formerly unobservable. Imagine how viewing previously invisible objects with a
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1.2 • The Scientific Methods

17

microscope or viewing Earth for the first time from space may have instantly changed our scientific theories and laws! What discoveries still await us in the future? The constant retesting and perfecting of our scientific laws and theories allows our knowledge of nature to progress. For this reason, many scientists are reluctant to say that their studies prove anything. By saying support instead of prove, it keeps the door open for future discoveries, even if they won’t occur for centuries or even millennia.
Check Your Understanding
6. Explain why scientists sometimes use a model rather than trying to analyze the behavior of the real system. a. Models are simpler to analyze. b. Models give more accurate results. c. Models provide more reliable predictions. d. Models do not require any computer calculations.
7. Describe the difference between a question, generated through observation, and a hypothesis. a. They are the same. b. A hypothesis has been thoroughly tested and found to be true. c. A hypothesis is a tentative assumption based on what is already known. d. A hypothesis is a broad explanation firmly supported by evidence.
8. What is a scientific model and how is it useful? a. A scientific model is a representation of something that can be easily studied directly. It is useful for studying things that can be easily analyzed by humans. b. A scientific model is a representation of something that is often too difficult to study directly. It is useful for studying a complex system or systems that humans cannot observe directly. c. A scientific model is a representation of scientific equipment. It is useful for studying working principles of scientific equipment. d. A scientific model is a representation of a laboratory where experiments are performed. It is useful for studying requirements needed inside the laboratory.
9. Which of the following statements is correct about the hypothesis? a. The hypothesis must be validated by scientific experiments. b. The hypothesis must not include any physical quantity. c. The hypothesis must be a short and concise statement. d. The hypothesis must apply to all the situations in the universe.
10. What is a scientific theory? a. A scientific theory is an explanation of natural phenomena that is supported by evidence. b. A scientific theory is an explanation of natural phenomena without the support of evidence. c. A scientific theory is an educated guess about the natural phenomena occurring in nature. d. A scientific theory is an uneducated guess about natural phenomena occurring in nature.
11. Compare and contrast a hypothesis and a scientific theory. a. A hypothesis is an explanation of the natural world with experimental support, while a scientific theory is an educated guess about a natural phenomenon. b. A hypothesis is an educated guess about natural phenomenon, while a scientific theory is an explanation of natural world with experimental support. c. A hypothesis is experimental evidence of a natural phenomenon, while a scientific theory is an explanation of the natural world with experimental support. d. A hypothesis is an explanation of the natural world with experimental support, while a scientific theory is experimental evidence of a natural phenomenon.

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Chapter 1 • What is Physics?

1.3 The Language of Physics: Physical Quantities and Units
Section Learning Objectives By the end of this section, you will be able to do the following:
• Associate physical quantities with their International System of Units (SI)and perform conversions among SI units using scientific notation
• Relate measurement uncertainty to significant figures and apply the rules for using significant figures in calculations
• Correctly create, label, and identify relationships in graphs using mathematical relationships (e.g., slope, y-intercept, inverse, quadratic and logarithmic)
Section Key Terms

accuracy

ampere

constant

conversion factor

dependent variable

derived units

English units

exponential relationship

fundamental physical units

independent variable

inverse relationship

inversely proportional

kilogram

linear relationship

logarithmic (log) scale

log-log plot

meter

method of adding percents

order of magnitude

precision

quadratic relationship

scientific notation second

semi-log plot

SI units

significant figures slope

uncertainty

variable

y-intercept

The Role of Units
Physicists, like other scientists, make observations and ask basic questions. For example, how big is an object? How much mass does it have? How far did it travel? To answer these questions, they make measurements with various instruments (e.g., meter stick, balance, stopwatch, etc.).
The measurements of physical quantities are expressed in terms of units, which are standardized values. For example, the length of a race, which is a physical quantity, can be expressed in meters (for sprinters) or kilometers (for long distance runners). Without standardized units, it would be extremely difficult for scientists to express and compare measured values in a meaningful way (Figure 1.13).

Figure 1.13 Distances given in unknown units are maddeningly useless.
All physical quantities in the International System of Units (SI) are expressed in terms of combinations of seven fundamental
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1.3 • The Language of Physics: Physical Quantities and Units

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physical units, which are units for: length, mass, time, electric current, temperature, amount of a substance, and luminous intensity.
SI Units: Fundamental and Derived Units
There are two major systems of units used in the world: SI units (acronym for the French Le Système International d’Unités, also known as the metric system), and English units (also known as the imperial system). English units were historically used in nations once ruled by the British Empire. Today, the United States is the only country that still uses English units extensively. Virtually every other country in the world now uses the metric system, which is the standard system agreed upon by scientists and mathematicians.
Some physical quantities are more fundamental than others. In physics, there are seven fundamental physical quantities that are measured in base or physical fundamental units: length, mass, time, electric current temperature, amount of substance, and luminous intensity. Units for other physical quantities (such as force, speed, and electric charge) described by mathematically combining these seven base units. In this course, we will mainly use five of these: length, mass, time, electric current and temperature. The units in which they are measured are the meter, kilogram, second, ampere, kelvin, mole, and candela (Table 1.1). All other units are made by mathematically combining the fundamental units. These are called derived units.

Quantity

Name Symbol

Length

Meter

m

Mass

Kilogram kg

Time

Second s

Electric current

Ampere a

Temperature

Kelvin

k

Amount of substance Mole

mol

Luminous intensity Candela cd

Table 1.1 SI Base Units

The Meter
The SI unit for length is the meter (m). The definition of the meter has changed over time to become more accurate and precise. The meter was first defined in 1791 as 1/10,000,000 of the distance from the equator to the North Pole. This measurement was improved in 1889 by redefining the meter to be the distance between two engraved lines on a platinum-iridium bar. (The bar is now housed at the International Bureau of Weights and Meaures, near Paris). By 1960, some distances could be measured more precisely by comparing them to wavelengths of light. The meter was redefined as 1,650,763.73 wavelengths of orange light emitted by krypton atoms. In 1983, the meter was given its present definition as the distance light travels in a vacuum in 1/ 299,792,458 of a second (Figure 1.14).

Figure 1.14 The meter is defined to be the distance light travels in 1/299,792,458 of a second through a vacuum. Distance traveled is speed multiplied by time.

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Chapter 1 • What is Physics?

The Kilogram
The SI unit for mass is the kilogram (kg). It is defined to be the mass of a platinum-iridium cylinder, housed at the International Bureau of Weights and Measures near Paris. Exact replicas of the standard kilogram cylinder are kept in numerous locations throughout the world, such as the National Institute of Standards and Technology in Gaithersburg, Maryland. The determination of all other masses can be done by comparing them with one of these standard kilograms.
The Second
The SI unit for time, the second (s) also has a long history. For many years it was defined as 1/86,400 of an average solar day. However, the average solar day is actually very gradually getting longer due to gradual slowing of Earth’s rotation. Accuracy in the fundamental units is essential, since all other measurements are derived from them. Therefore, a new standard was adopted to define the second in terms of a non-varying, or constant, physical phenomenon. One constant phenomenon is the very steady vibration of Cesium atoms, which can be observed and counted. This vibration forms the basis of the cesium atomic clock. In 1967, the second was redefined as the time required for 9,192,631,770 Cesium atom vibrations (Figure 1.15).

Figure 1.15 An atomic clock such as this one uses the vibrations of cesium atoms to keep time to a precision of one microsecond per year. The fundamental unit of time, the second, is based on such clocks. This image is looking down from the top of an atomic clock. (Steve Jurvetson/Flickr)
The Ampere
Electric current is measured in the ampere (A), named after Andre Ampere. You have probably heard of amperes, or amps, when people discuss electrical currents or electrical devices. Understanding an ampere requires a basic understanding of electricity and magnetism, something that will be explored in depth in later chapters of this book. Basically, two parallel wires with an electric current running through them will produce an attractive force on each other. One ampere is defined as the amount of electric current that will produce an attractive force of 2.7 10–7 newton per meter of separation between the two wires (the newton is the derived unit of force).
Kelvins
The SI unit of temperature is the kelvin (or kelvins, but not degrees kelvin). This scale is named after physicist William Thomson, Lord Kelvin, who was the first to call for an absolute temperature scale. The Kelvin scale is based on absolute zero. This is the point at which all thermal energy has been removed from all atoms or molecules in a system. This temperature, 0 K, is equal to −273.15 °C and −459.67 °F. Conveniently, the Kelvin scale actually changes in the same way as the Celsius scale. For example, the freezing point (0 °C) and boiling points of water (100 °C) are 100 degrees apart on the Celsius scale. These two temperatures are also 100 kelvins apart (freezing point = 273.15 K; boiling point = 373.15 K).
Metric Prefixes
Physical objects or phenomena may vary widely. For example, the size of objects varies from something very small (like an atom)
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1.3 • The Language of Physics: Physical Quantities and Units

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to something very large (like a star). Yet the standard metric unit of length is the meter. So, the metric system includes many prefixes that can be attached to a unit. Each prefix is based on factors of 10 (10, 100, 1,000, etc., as well as 0.1, 0.01, 0.001, etc.). Table 1.2 gives the metric prefixes and symbols used to denote the different various factors of 10 in the metric system.

Prefix Symbol Value[1]

Example Name

Example Symbol

Example Value

Example Description

exa

E

peta P

tera T

giga G

mega M

kilo

k

hector h

deka da

____ ____

deci d

centi c

milli m

micro µ

nano n

pico p

femto f

1018

Exameter

Em

1015

Petasecond

Ps

1012

Terawatt

TW

109

Gigahertz

GHz

106

Megacurie

MCi

103

Kilometer

km

102

Hectoliter

hL

101

Dekagram

dag

100 (=1)

10–1

Deciliter

dL

10–2

Centimeter

Cm

10–3

Millimeter

Mm

10–6

Micrometer

µm

10–9

Nanogram

Ng

10–12

Picofarad

pF

10–15

Femtometer

Fm

1018 m
1015 s 1012 W 109 Hz 106 Ci 103 m 102 L 101 g

Distance light travels in a century 30 million years Powerful laser output A microwave frequency High radioactivity About 6/10 mile 26 gallons Teaspoon of butter

10–1 L 10–2 m 10–3 m 10–6 m 10–9 g 10–12 F 10–15 m

Less than half a soda Fingertip thickness Flea at its shoulder Detail in microscope Small speck of dust Small capacitor in radio Size of a proton

atto a

10–18

Attosecond

as

10–18 s

Time light takes to cross an atom

Table 1.2 Metric Prefixes for Powers of 10 and Their Symbols [1]See Appendix A for a discussion of powers of 10. Note—Some examples are approximate.

The metric system is convenient because conversions between metric units can be done simply by moving the decimal place of a number. This is because the metric prefixes are sequential powers of 10. There are 100 centimeters in a meter, 1000 meters in a kilometer, and so on. In nonmetric systems, such as U.S. customary units, the relationships are less simple—there are 12 inches in a foot, 5,280 feet in a mile, 4 quarts in a gallon, and so on. Another advantage of the metric system is that the same unit can be used over extremely large ranges of values simply by switching to the most-appropriate metric prefix. For example, distances in meters are suitable for building construction, but kilometers are used to describe road construction. Therefore, with the metric system, there is no need to invent new units when measuring very small or very large objects—you just have to move the decimal

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Chapter 1 • What is Physics?

point (and use the appropriate prefix).
Known Ranges of Length, Mass, and Time
Table 1.3 lists known lengths, masses, and time measurements. You can see that scientists use a range of measurement units. This wide range demonstrates the vastness and complexity of the universe, as well as the breadth of phenomena physicists study. As you examine this table, note how the metric system allows us to discuss and compare an enormous range of phenomena, using one system of measurement (Figure 1.16 and Figure 1.17).

Length (m)

Phenomenon Measured

Mass (Kg)

Phenomenon Measured[1]

Time (s)

Phenomenon Measured[1]

10–18

Present experimental limit to smallest observable detail

10–30

Mass of an electron (9.11 10–31 kg)

10–23

Time for light to cross a proton

10–15

Diameter of a proton

10–27

Mass of a hydrogen atom (1.67 10–27 kg)

10–22

Mean life of an extremely unstable nucleus

1014

Diameter of a uranium nucleus

10–15 Mass of a bacterium

10–15 Time for one oscillation of a visible light

10–10

Diameter of a hydrogen atom

10–5 Mass of a mosquito

10–13 Time for one vibration of an atom in a solid

10–8

Thickness of membranes in cell of living organism

10–2

Mass of a hummingbird

10–8

Time for one oscillation of an FM radio wave

10–6

Wavelength of visible light

10–3

Size of a grain of sand

1

Height of a 4-year-old child

102

Length of a football field

1

Mass of a liter of water (about a quart)

102

Mass of a person

103

Mass of a car

108

Mass of a large ship

10–3 Duration of a nerve impulse

1

Time for one heartbeat

105

One day (8.64 104 s)

107

One year (3.16 107 s)

104

Greatest ocean depth

1012 Mass of a large iceberg

109

About half the life

expectancy of a human

107

Diameter of Earth

1015

Mass of the nucleus of a comet

1011 Recorded history

1011

Distance from Earth to the sun

1023

Mass of the moon (7.35 1022 kg)

1017 Age of Earth

1016

Distance traveled by light in 1 year 1025

Mass of Earth (5.97 1024

1018 Age of the universe

(a light year)

kg)

1021

Diameter of the Milky Way Galaxy 1030

Mass of the Sun (1.99 1024 kg)

Table 1.3 Approximate Values of Length, Mass, and Time [1] More precise values are in parentheses.

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Length (m)

Phenomenon Measured

Mass (Kg)

Phenomenon Measured[1]

Time (s)

1022

Distance from Earth to the nearest large galaxy (Andromeda)

1042

Mass of the Milky Way galaxy (current upper limit)

1026

Distance from Earth to the edges 1053

Mass of the known universe

of the known universe

(current upper limit)

Table 1.3 Approximate Values of Length, Mass, and Time [1] More precise values are in parentheses.

Phenomenon Measured[1]

Figure 1.16 Tiny phytoplankton float among crystals of ice in the Antarctic Sea. They range from a few micrometers to as much as 2 millimeters in length. (Prof. Gordon T. Taylor, Stony Brook University; NOAA Corps Collections)
Figure 1.17 Galaxies collide 2.4 billion light years away from Earth. The tremendous range of observable phenomena in nature challenges the imagination. (NASA/CXC/UVic./A. Mahdavi et al. Optical/lensing: CFHT/UVic./H. Hoekstra et al.)
Using Scientific Notation with Physical Measurements
Scientific notation is a way of writing numbers that are too large or small to be conveniently written as a decimal. For example, consider the number 840,000,000,000,000. It’s a rather large number to write out. The scientific notation for this number is 8.40 1014. Scientific notation follows this general format
In this format x is the value of the measurement with all placeholder zeros removed. In the example above, x is 8.4. The x is multiplied by a factor, 10y, which indicates the number of placeholder zeros in the measurement. Placeholder zeros are those at the end of a number that is 10 or greater, and at the beginning of a decimal number that is less than 1. In the example above, the factor is 1014. This tells you that you should move the decimal point 14 positions to the right, filling in placeholder zeros as you go. In this case, moving the decimal point 14 places creates only 13 placeholder zeros, indicating that the actual measurement value is 840,000,000,000,000.

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Chapter 1 • What is Physics?

Numbers that are fractions can be indicated by scientific notation as well. Consider the number 0.0000045. Its scientific notation is 4.5 10–6. Its scientific notation has the same format
Here, x is 4.5. However, the value of y in the 10y factor is negative, which indicates that the measurement is a fraction of 1. Therefore, we move the decimal place to the left, for a negative y. In our example of 4.5 10–6, the decimal point would be moved to the left six times to yield the original number, which would be 0.0000045.
The term order of magnitude refers to the power of 10 when numbers are expressed in scientific notation. Quantities that have the same power of 10 when expressed in scientific notation, or come close to it, are said to be of the same order of magnitude. For example, the number 800 can be written as 8 102, and the number 450 can be written as 4.5 102. Both numbers have the same value for y. Therefore, 800 and 450 are of the same order of magnitude. Similarly, 101 and 99 would be regarded as the same order of magnitude, 102. Order of magnitude can be thought of as a ballpark estimate for the scale of a value. The diameter of an atom is on the order of 10−9 m, while the diameter of the sun is on the order of 109 m. These two values are 18 orders of magnitude apart.
Scientists make frequent use of scientific notation because of the vast range of physical measurements possible in the universe, such as the distance from Earth to the moon (Figure 1.18), or to the nearest star.

Figure 1.18 The distance from Earth to the moon may seem immense, but it is just a tiny fraction of the distance from Earth to our closest neighboring star. (NASA)
Unit Conversion and Dimensional Analysis
It is often necessary to convert from one type of unit to another. For example, if you are reading a European cookbook in the United States, some quantities may be expressed in liters and you need to convert them to cups. A Canadian tourist driving through the United States might want to convert miles to kilometers, to have a sense of how far away his next destination is. A doctor in the United States might convert a patient’s weight in pounds to kilograms. Let’s consider a simple example of how to convert units within the metric system. How can we want to convert 1 hour to seconds? Next, we need to determine a conversion factor relating meters to kilometers. A conversion factor is a ratio expressing how many of one unit are equal to another unit. A conversion factor is simply a fraction which equals 1. You can multiply any number by 1 and get the same value. When you multiply a number by a conversion factor, you are simply multiplying it by one. For example, the following are conversion factors: (1 foot)/(12 inches) = 1 to convert inches to feet, (1 meter)/(100 centimeters) = 1 to convert centimeters to meters, (1 minute)/(60 seconds) = 1 to convert seconds to minutes. In this case, we know that there are 1,000 meters in 1 kilometer. Now we can set up our unit conversion. We will write the units that we have and then multiply them by the conversion factor (1 km/1,000m) = 1, so we are simply multiplying 80m by 1:
1.1
When there is a unit in the original number, and a unit in the denominator (bottom) of the conversion factor, the units cancel. In this case, hours and minutes cancel and the value in seconds remains. You can use this method to convert between any types of unit, including between the U.S. customary system and metric system. Notice also that, although you can multiply and divide units algebraically, you cannot add or subtract different units. An expression like 10 km + 5 kg makes no sense. Even adding two lengths in different units, such as 10 km + 20 m does not make sense. You express both lengths in the same unit. See Appendix C for a more complete list of conversion factors.
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WORKED EXAMPLE
Unit Conversions: A Short Drive Home
Suppose that you drive the 10.0 km from your university to home in 20.0 min. Calculate your average speed (a) in kilometers per hour (km/h) and (b) in meters per second (m/s). (Note—Average speed is distance traveled divided by time of travel.) Strategy First we calculate the average speed using the given units. Then we can get the average speed into the desired units by picking the correct conversion factor and multiplying by it. The correct conversion factor is the one that cancels the unwanted unit and leaves the desired unit in its place.
Solution for (a) 1. Calculate average speed. Average speed is distance traveled divided by time of travel. (Take this definition as a given for
now—average speed and other motion concepts will be covered in a later module.) In equation form,

2. Substitute the given values for distance and time.

3. Convert km/min to km/h: multiply by the conversion factor that will cancel minutes and leave hours. That conversion factor

is

. Thus,

Discussion for (a) To check your answer, consider the following:
1. Be sure that you have properly cancelled the units in the unit conversion. If you have written the unit conversion factor upside down, the units will not cancel properly in the equation. If you accidentally get the ratio upside down, then the units will not cancel; rather, they will give you the wrong units as follows

which are obviously not the desired units of km/h.
2. Check that the units of the final answer are the desired units. The problem asked us to solve for average speed in units of km/h and we have indeed obtained these units.
3. Check the significant figures. Because each of the values given in the problem has three significant figures, the answer should also have three significant figures. The answer 30.0 km/h does indeed have three significant figures, so this is appropriate. Note that the significant figures in the conversion factor are not relevant because an hour is defined to be 60 min, so the precision of the conversion factor is perfect.
4. Next, check whether the answer is reasonable. Let us consider some information from the problem—if you travel 10 km in a third of an hour (20 min), you would travel three times that far in an hour. The answer does seem reasonable.
Solution (b) There are several ways to convert the average speed into meters per second.
1. Start with the answer to (a) and convert km/h to m/s. Two conversion factors are needed—one to convert hours to seconds, and another to convert kilometers to meters.
2. Multiplying by these yields

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Chapter 1 • What is Physics?

Discussion for (b) If we had started with 0.500 km/min, we would have needed different conversion factors, but the answer would have been the same: 8.33 m/s.
You may have noted that the answers in the worked example just covered were given to three digits. Why? When do you need to be concerned about the number of digits in something you calculate? Why not write down all the digits your calculator produces?

WORKED EXAMPLE

Using Physics to Evaluate Promotional Materials
A commemorative coin that is 2″ in diameter is advertised to be plated with 15 mg of gold. If the density of gold is 19.3 g/cc, and the amount of gold around the edge of the coin can be ignored, what is the thickness of the gold on the top and bottom faces of the coin?

Strategy To solve this problem, the volume of the gold needs to be determined using the gold’s mass and density. Half of that volume is distributed on each face of the coin, and, for each face, the gold can be represented as a cylinder that is 2″ in diameter with a height equal to the thickness. Use the volume formula for a cylinder to determine the thickness.

Solution The mass of the gold is given by the formula

where

and V is the volume. Solving for

the volume gives

If t is the thickness, the volume corresponding to half the gold is

where the 1″ radius

has been converted to cm. Solving for the thickness gives

Discussion The amount of gold used is stated to be 15 mg, which is equivalent to a thickness of about 0.00019 mm. The mass figure may make the amount of gold sound larger, both because the number is much bigger (15 versus 0.00019), and because people may have a more intuitive feel for how much a millimeter is than for how much a milligram is. A simple analysis of this sort can clarify the significance of claims made by advertisers.

Accuracy, Precision and Significant Figures
Science is based on experimentation that requires good measurements. The validity of a measurement can be described in terms of its accuracy and its precision (see Figure 1.19 and Figure 1.20). Accuracy is how close a measurement is to the correct value for that measurement. For example, let us say that you are measuring the length of standard piece of printer paper. The packaging in which you purchased the paper states that it is 11 inches long, and suppose this stated value is correct. You measure the length of the paper three times and obtain the following measurements: 11.1 inches, 11.2 inches, and 10.9 inches. These measurements are quite accurate because they are very close to the correct value of 11.0 inches. In contrast, if you had obtained a measurement of 12 inches, your measurement would not be very accurate. This is why measuring instruments are calibrated based on a known measurement. If the instrument consistently returns the correct value of the known measurement, it is safe for use in finding unknown values.

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Figure 1.19 A double-pan mechanical balance is used to compare different masses. Usually an object with unknown mass is placed in one pan and objects of known mass are placed in the other pan. When the bar that connects the two pans is horizontal, then the masses in both pans are equal. The known masses are typically metal cylinders of standard mass such as 1 gram, 10 grams, and 100 grams. (Serge Melki)
Figure 1.20 Whereas a mechanical balance may only read the mass of an object to the nearest tenth of a gram, some digital scales can measure the mass of an object up to the nearest thousandth of a gram. As in other measuring devices, the precision of a scale is limited to the last measured figures. This is the hundredths place in the scale pictured here. (Splarka, Wikimedia Commons)
Precision states how well repeated measurements of something generate the same or similar results. Therefore, the precision of measurements refers to how close together the measurements are when you measure the same thing several times. One way to analyze the precision of measurements would be to determine the range, or difference between the lowest and the highest measured values. In the case of the printer paper measurements, the lowest value was 10.9 inches and the highest value was 11.2 inches. Thus, the measured values deviated from each other by, at most, 0.3 inches. These measurements were reasonably precise because they varied by only a fraction of an inch. However, if the measured values had been 10.9 inches, 11.1 inches, and 11.9 inches, then the measurements would not be very precise because there is a lot of variation from one measurement to another. The measurements in the paper example are both accurate and precise, but in some cases, measurements are accurate but not precise, or they are precise but not accurate. Let us consider a GPS system that is attempting to locate the position of a restaurant in a city. Think of the restaurant location as existing at the center of a bull’s-eye target. Then think of each GPS attempt to locate the restaurant as a black dot on the bull’s eye. In Figure 1.21, you can see that the GPS measurements are spread far apart from each other, but they are all relatively close to the actual location of the restaurant at the center of the target. This indicates a low precision, high accuracy measuring system. However, in Figure 1.22, the GPS measurements are concentrated quite closely to one another, but they are far away from the target location. This indicates a high precision, low accuracy measuring system. Finally, in Figure 1.23, the GPS is both precise and accurate, allowing the restaurant to be located.

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Chapter 1 • What is Physics?

Figure 1.21 A GPS system attempts to locate a restaurant at the center of the bull’s-eye. The black dots represent each attempt to pinpoint the location of the restaurant. The dots are spread out quite far apart from one another, indicating low precision, but they are each rather close to the actual location of the restaurant, indicating high accuracy. (Dark Evil)
Figure 1.22 In this figure, the dots are concentrated close to one another, indicating high precision, but they are rather far away from the actual location of the restaurant, indicating low accuracy. (Dark Evil)
Figure 1.23 In this figure, the dots are concentrated close to one another, indicating high precision, but they are rather far away from the actual location of the restaurant, indicating low accuracy. (Dark Evil)
Uncertainty
The accuracy and precision of a measuring system determine the uncertainty of its measurements. Uncertainty is a way to describe how much your measured value deviates from the actual value that the object has. If your measurements are not very accurate or precise, then the uncertainty of your values will be very high. In more general terms, uncertainty can be thought of as a disclaimer for your measured values. For example, if someone asked you to provide the mileage on your car, you might say that it is 45,000 miles, plus or minus 500 miles. The plus or minus amount is the uncertainty in your value. That is, you are indicating that the actual mileage of your car might be as low as 44,500 miles or as high as 45,500 miles, or anywhere in between. All measurements contain some amount of uncertainty. In our example of measuring the length of the paper, we might say that the length of the paper is 11 inches plus or minus 0.2 inches or 11.0 ± 0.2 inches. The uncertainty in a
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29

measurement, A, is often denoted as δA ("delta A"),
The factors contributing to uncertainty in a measurement include the following:
1. Limitations of the measuring device 2. The skill of the person making the measurement 3. Irregularities in the object being measured 4. Any other factors that affect the outcome (highly dependent on the situation)
In the printer paper example uncertainty could be caused by: the fact that the smallest division on the ruler is 0.1 inches, the person using the ruler has bad eyesight, or uncertainty caused by the paper cutting machine (e.g., one side of the paper is slightly longer than the other.) It is good practice to carefully consider all possible sources of uncertainty in a measurement and reduce or eliminate them,
Percent Uncertainty
One method of expressing uncertainty is as a percent of the measured value. If a measurement, A, is expressed with uncertainty, δA, the percent uncertainty is
1.2

WORKED EXAMPLE
Calculating Percent Uncertainty: A Bag of Apples
A grocery store sells 5-lb bags of apples. You purchase four bags over the course of a month and weigh the apples each time. You obtain the following measurements:
• Week 1 weight: • Week 2 weight: • Week 3 weight: • Week 4 weight:
You determine that the weight of the 5 lb bag has an uncertainty of ±0.4 lb. What is the percent uncertainty of the bag’s weight? Strategy First, observe that the expected value of the bag’s weight, , is 5 lb. The uncertainty in this value, , is 0.4 lb. We can use the following equation to determine the percent uncertainty of the weight

Solution Plug the known values into the equation

Discussion We can conclude that the weight of the apple bag is 5 lb ± 8 percent. Consider how this percent uncertainty would change if the bag of apples were half as heavy, but the uncertainty in the weight remained the same. Hint for future calculations: when calculating percent uncertainty, always remember that you must multiply the fraction by 100 percent. If you do not do this, you will have a decimal quantity, not a percent value.
Uncertainty in Calculations
There is an uncertainty in anything calculated from measured quantities. For example, the area of a floor calculated from measurements of its length and width has an uncertainty because the both the length and width have uncertainties. How big is the uncertainty in something you calculate by multiplication or division? If the measurements in the calculation have small uncertainties (a few percent or less), then the method of adding percents can be used. This method says that the percent uncertainty in a quantity calculated by multiplication or division is the sum of the percent uncertainties in the items used to make the calculation. For example, if a floor has a length of 4.00 m and a width of 3.00 m, with uncertainties of 2 percent and 1

30

Chapter 1 • What is Physics?

percent, respectively, then the area of the floor is 12.0 m2 and has an uncertainty of 3 percent (expressed as an area this is 0.36 m2, which we round to 0.4 m2 since the area of the floor is given to a tenth of a square meter).
For a quick demonstration of the accuracy, precision, and uncertainty of measurements based upon the units of measurement, try this simulation (http://openstax.org/l/28precision) . You will have the opportunity to measure the length and weight of a desk, using milli- versus centi- units. Which do you think will provide greater accuracy, precision and uncertainty when measuring the desk and the notepad in the simulation? Consider how the nature of the hypothesis or research question might influence how precise of a measuring tool you need to collect data.
Precision of Measuring Tools and Significant Figures
An important factor in the accuracy and precision of measurements is the precision of the measuring tool. In general, a precise measuring tool is one that can measure values in very small increments. For example, consider measuring the thickness of a coin. A standard ruler can measure thickness to the nearest millimeter, while a micrometer can measure the thickness to the nearest 0.005 millimeter. The micrometer is a more precise measuring tool because it can measure extremely small differences in thickness. The more precise the measuring tool, the more precise and accurate the measurements can be.
When we express measured values, we can only list as many digits as we initially measured with our measuring tool (such as the rulers shown in Figure 1.24). For example, if you use a standard ruler to measure the length of a stick, you may measure it with a decimeter ruler as 3.6 cm. You could not express this value as 3.65 cm because your measuring tool was not precise enough to measure a hundredth of a centimeter. It should be noted that the last digit in a measured value has been estimated in some way by the person performing the measurement. For example, the person measuring the length of a stick with a ruler notices that the stick length seems to be somewhere in between 36 mm and 37 mm. He or she must estimate the value of the last digit. The rule is that the last digit written down in a measurement is the first digit with some uncertainty. For example, the last measured value 36.5 mm has three digits, or three significant figures. The number of significant figures in a measurement indicates the precision of the measuring tool. The more precise a measuring tool is, the greater the number of significant figures it can report.

Figure 1.24 Three metric rulers are shown. The first ruler is in decimeters and can measure point three decimeters. The second ruler is in centimeters long and can measure three point six centimeters. The last ruler is in millimeters and can measure thirty-six point five millimeters.
Zeros
Special consideration is given to zeros when counting significant figures. For example, the zeros in 0.053 are not significant because they are only placeholders that locate the decimal point. There are two significant figures in 0.053—the 5 and the 3. However, if the zero occurs between other significant figures, the zeros are significant. For example, both zeros in 10.053 are significant, as these zeros were actually measured. Therefore, the 10.053 placeholder has five significant figures. The zeros in 1300 may or may not be significant, depending on the style of writing numbers. They could mean the number is known to the last zero, or the zeros could be placeholders. So 1300 could have two, three, or four significant figures. To avoid this ambiguity,
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31

write 1300 in scientific notation as 1.3 × 103. Only significant figures are given in the x factor for a number in scientific notation

(in the form

). Therefore, we know that 1 and 3 are the only significant digits in this number. In summary, zeros are

significant except when they serve only as placeholders. Table 1.4 provides examples of the number of significant figures in

various numbers.

Number

Significant Figures

Rationale

1.657

4

There are no zeros and all non-zero numbers are always significant.

0.4578

4

The first zero is only a placeholder for the decimal point.

0.000458 3

The first four zeros are placeholders needed to report the data to the ten-thoudsandths place.

2000.56 6

The three zeros are significant here because they occur between other significant figures.

45,600

3

With no underlines or scientific notation, we assume that the last two zeros are placeholders and are not significant.

15895000 7

The two underlined zeros are significant, while the last zero is not, as it is not underlined.

5.457 1013

4

In scientific notation, all numbers reported in front of the multiplication sign are significant

6.520

10–23

4

In scientific notation, all numbers reported in front of the multiplication sign are significant, including zeros.

Table 1.4

Significant Figures in Calculations
When combining measurements with different degrees of accuracy and precision, the number of significant digits in the final answer can be no greater than the number of significant digits in the least precise measured value. There are two different rules, one for multiplication and division and another rule for addition and subtraction, as discussed below.

1. For multiplication and division: The answer should have the same number of significant figures as the starting value with

the fewest significant figures. For example, the area of a circle can be calculated from its radius using

. Let us see

how many significant figures the area will have if the radius has only two significant figures, for example, r = 2.0 m. Then,

using a calculator that keeps eight significant figures, you would get

But because the radius has only two significant figures, the area calculated is meaningful only to two significant figures or

even though the value of is meaningful to at least eight digits.
2. For addition and subtraction: The answer should have the same number places (e.g. tens place, ones place, tenths place, etc.) as the least-precise starting value. Suppose that you buy 7.56 kg of potatoes in a grocery store as measured with a scale having a precision of 0.01 kg. Then you drop off 6.052 kg of potatoes at your laboratory as measured by a scale with a precision of 0.001 kg. Finally, you go home and add 13.7 kg of potatoes as measured by a bathroom scale with a precision of 0.1 kg. How many kilograms of potatoes do you now have, and how many significant figures are appropriate in the answer? The mass is found by simple addition and subtraction:

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Chapter 1 • What is Physics?

The least precise measurement is 13.7 kg. This measurement is expressed to the 0.1 decimal place, so our final answer must also be expressed to the 0.1 decimal place. Thus, the answer should be rounded to the tenths place, giving 15.2 kg. The same is true for non-decimal numbers. For example,

We cannot report the decimal places in the answer because 2 has no decimal places that would be significant. Therefore, we can only report to the ones place.

It is a good idea to keep extra significant figures while calculating, and to round off to the correct number of significant

figures only in the final answers. The reason is that small errors from rounding while calculating can sometimes produce

significant errors in the final answer. As an example, try calculating

to obtain a final answer

to only two significant figures. Keeping all significant during the calculation gives 48. Rounding to two significant figures

in the middle of the calculation changes it to

which is way off. You would similarly

avoid rounding in the middle of the calculation in counting and in doing accounting, where many small numbers need to

be added and subtracted accurately to give possibly much larger final numbers.

Significant Figures in this Text

In this textbook, most numbers are assumed to have three significant figures. Furthermore, consistent numbers of significant

figures are used in all worked examples. You will note that an answer given to three digits is based on input good to at least three

digits. If the input has fewer significant figures, the answer will also have fewer significant figures. Care is also taken that the

number of significant figures is reasonable for the situation posed. In some topics, such as optics, more than three significant

figures will be used. Finally, if a number is exact, such as the 2 in the formula,

, it does not affect the number of

significant figures in a calculation.

WORKED EXAMPLE
Approximating Vast Numbers: a Trillion Dollars
The U.S. federal deficit in the 2008 fiscal year was a little greater than $10 trillion. Most of us do not have any concept of how much even one trillion actually is. Suppose that you were given a trillion dollars in $100 bills. If you made 100-bill stacks, like that shown in Figure 1.25, and used them to evenly cover a football field (between the end zones), make an approximation of how high the money pile would become. (We will use feet/inches rather than meters here because football fields are measured in yards.) One of your friends says 3 in., while another says 10 ft. What do you think?

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33

Figure 1.25 A bank stack contains one hundred $100 bills, and is worth $10,000. How many bank stacks make up a trillion dollars? (Andrew Magill)
Strategy When you imagine the situation, you probably envision thousands of small stacks of 100 wrapped $100 bills, such as you might see in movies or at a bank. Since this is an easy-to-approximate quantity, let us start there. We can find the volume of a stack of 100 bills, find out how many stacks make up one trillion dollars, and then set this volume equal to the area of the football field multiplied by the unknown height.
Solution 1. Calculate the volume of a stack of 100 bills. The dimensions of a single bill are approximately 3 in. by 6 in. A stack of 100 of
these is about 0.5 in. thick. So the total volume of a stack of 100 bills is

2. Calculate the number of stacks. Note that a trillion dollars is equal to

equal to

or

. The number of stacks you will have is

, and a stack of one-hundred

bills is

1.3

3. Calculate the area of a football field in square inches. The area of a football field is

, which gives

. Because we are working in inches, we need to convert square yards to square inches

This conversion gives us calculations.)

for the area of the field. (Note that we are using only one significant figure in these

4. Calculate the total volume of the bills. The volume of all the $100-bill stacks is

5. Calculate the height. To determine the height of the bills, use the following equation

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Chapter 1 • What is Physics?

The height of the money will be about 100 in. high. Converting this value to feet gives

Discussion The final approximate value is much higher than the early estimate of 3 in., but the other early estimate of 10 ft (120 in.) was roughly correct. How did the approximation measure up to your first guess? What can this exercise tell you in terms of rough guesstimates versus carefully calculated approximations?

In the example above, the final approximate value is much higher than the first friend’s early estimate of 3 in. However, the other friend’s early estimate of 10 ft. (120 in.) was roughly correct. How did the approximation measure up to your first guess? What can this exercise suggest about the value of rough guesstimates versus carefully calculated approximations?
Graphing in Physics
Most results in science are presented in scientific journal articles using graphs. Graphs present data in a way that is easy to visualize for humans in general, especially someone unfamiliar with what is being studied. They are also useful for presenting large amounts of data or data with complicated trends in an easily-readable way.
One commonly-used graph in physics and other sciences is the line graph, probably because it is the best graph for showing how one quantity changes in response to the other. Let’s build a line graph based on the data in Table 1.5, which shows the measured distance that a train travels from its station versus time. Our two variables, or things that change along the graph, are time in minutes, and distance from the station, in kilometers. Remember that measured data may not have perfect accuracy.

Time (min) Distance from Station (km)

0

0

10

24

20

36

30

60

40

84

50

97

60

116

70

140

Table 1.5

1. Draw the two axes. The horizontal axis, or x-axis, shows the independent variable, which is the variable that is controlled or manipulated. The vertical axis, or y-axis, shows the dependent variable, the non-manipulated variable that changes with (or is dependent on) the value of the independent variable. In the data above, time is the independent variable and should be plotted on the x-axis. Distance from the station is the dependent variable and should be plotted on the y-axis.

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1.3 • The Language of Physics: Physical Quantities and Units

35

2. Label each axes on the graph with the name of each variable, followed by the symbol for its units in parentheses. Be sure to leave room so that you can number each axis. In this example, use Time (min) as the label for the x-axis.
3. Next, you must determine the best scale to use for numbering each axis. Because the time values on the x-axis are taken every 10 minutes, we could easily number the x-axis from 0 to 70 minutes with a tick mark every 10 minutes. Likewise, the y-axis scale should start low enough and continue high enough to include all of the distance from station values. A scale from 0 km to 160 km should suffice, perhaps with a tick mark every 10 km.
In general, you want to pick a scale for both axes that 1) shows all of your data, and 2) makes it easy to identify trends in your data. If you make your scale too large, it will be harder to see how your data change. Likewise, the smaller and more fine you make your scale, the more space you will need to make the graph. The number of significant figures in the axis values should be coarser than the number of significant figures in the measurements.
4. Now that your axes are ready, you can begin plotting your data. For the first data point, count along the x-axis until you find the 10 min tick mark. Then, count up from that point to the 10 km tick mark on the y-axis, and approximate where 22 km is along the y-axis. Place a dot at this location. Repeat for the other six data points (Figure 1.26).

Figure 1.26 The graph of the train’s distance from the station versus time from the exercise above.
5. Add a title to the top of the graph to state what the graph is describing, such as the y-axis parameter vs. the x-axis parameter. In the graph shown here, the title is train motion. It could also be titled distance of the train from the station vs. time.
6. Finally, with data points now on the graph, you should draw a trend line (Figure 1.27). The trend line represents the dependence you think the graph represents, so that the person who looks at your graph can see how close it is to the real data. In the present case, since the data points look like they ought to fall on a straight line, you would draw a straight line as the trend line. Draw it to come closest to all the points. Real data may have some inaccuracies, and the plotted points may not all fall on the trend line. In some cases, none of the data points fall exactly on the trend line.

36

Chapter 1 • What is Physics?

Figure 1.27 The completed graph with the trend line included.
Analyzing a Graph Using Its Equation
One way to get a quick snapshot of a dataset is to look at the equation of its trend line. If the graph produces a straight line, the equation of the trend line takes the form
The b in the equation is the y-intercept while the m in the equation is the slope. The y-intercept tells you at what y value the line intersects the y-axis. In the case of the graph above, the y-intercept occurs at 0, at the very beginning of the graph. The y-intercept, therefore, lets you know immediately where on the y-axis the plot line begins. The m in the equation is the slope. This value describes how much the line on the graph moves up or down on the y-axis along the line’s length. The slope is found using the following equation
In order to solve this equation, you need to pick two points on the line (preferably far apart on the line so the slope you calculate describes the line accurately). The quantities Y2 and Y1 represent the y-values from the two points on the line (not data points) that you picked, while X2 and X1 represent the two x-values of the those points. What can the slope value tell you about the graph? The slope of a perfectly horizontal line will equal zero, while the slope of a perfectly vertical line will be undefined because you cannot divide by zero. A positive slope indicates that the line moves up the y-axis as the x-value increases while a negative slope means that the line moves down the y-axis. The more negative or positive the slope is, the steeper the line moves up or down, respectively. The slope of our graph in Figure 1.26 is calculated below based on the two endpoints of the line
Equation of line: Because the x axis is time in minutes, we would actually be more likely to use the time t as the independent (x-axis) variable and write the equation as
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1.3 • The Language of Physics: Physical Quantities and Units

37

1.4

The formula

only applies to linear relationships, or ones that produce a straight line. Another common type of line

in physics is the quadratic relationship, which occurs when one of the variables is squared. One quadratic relationship in

physics is the relation between the speed of an object its centripetal acceleration, which is used to determine the force needed to

keep an object moving in a circle. Another common relationship in physics is the inverse relationship, in which one variable

decreases whenever the other variable increases. An example in physics is Coulomb’s law. As the distance between two charged

objects increases, the electrical force between the two charged objects decreases. Inverse proportionality, such the relation

between x and y in the equation

for some number k, is one particular kind of inverse relationship. A third commonly-seen relationship is the exponential relationship, in which a change in the independent variable produces a proportional change in the dependent variable. As the value of the dependent variable gets larger, its rate of growth also increases. For example, bacteria often reproduce at an exponential rate when grown under ideal conditions. As each generation passes, there are more and more bacteria to reproduce. As a result, the growth rate of the bacterial population increases every generation (Figure 1.28).

Figure 1.28 Examples of (a) linear, (b) quadratic, (c) inverse, and (d) exponential relationship graphs.
Using Logarithmic Scales in Graphing
Sometimes a variable can have a very large range of values. This presents a problem when you’re trying to figure out the best scale to use for your graph’s axes. One option is to use a logarithmic (log) scale. In a logarithmic scale, the value each mark labels

38

Chapter 1 • What is Physics?

is the previous mark’s value multiplied by some constant. For a log base 10 scale, each mark labels a value that is 10 times the value of the mark before it. Therefore, a base 10 logarithmic scale would be numbered: 0, 10, 100, 1,000, etc. You can see how the logarithmic scale covers a much larger range of values than the corresponding linear scale, in which the marks would label the values 0, 10, 20, 30, and so on.
If you use a logarithmic scale on one axis of the graph and a linear scale on the other axis, you are using a semi-log plot. The Richter scale, which measures the strength of earthquakes, uses a semi-log plot. The degree of ground movement is plotted on a logarithmic scale against the assigned intensity level of the earthquake, which ranges linearly from 1-10 (Figure 1.29 (a)).
If a graph has both axes in a logarithmic scale, then it is referred to as a log-log plot. The relationship between the wavelength and frequency of electromagnetic radiation such as light is usually shown as a log-log plot (Figure 1.29 (b)). Log-log plots are also commonly used to describe exponential functions, such as radioactive decay.

Figure 1.29 (a) The Richter scale uses a log base 10 scale on its y-axis (microns of amplified maximum ground motion). (b) The relationship between the frequency and wavelength of electromagnetic radiation can be plotted as a straight line if a log-log plot is used.
Virtual Physics Graphing Lines
In this simulation you will examine how changing the slope and y-intercept of an equation changes the appearance of a plotted line. Select slope-intercept form and drag the blue circles along the line to change the line’s characteristics. Then, play the line game and see if you can determine the slope or y-intercept of a given line. Click to view content (https://phet.colorado.edu/sims/html/graphing-lines/latest/graphing-lines_en.html)
GRASP CHECK
How would the following changes affect a line that is neither horizontal nor vertical and has a positive slope? 1. increase the slope but keeping the y-intercept constant 2. increase the y-intercept but keeping the slope constant
a. Increasing the slope will cause the line to rotate clockwise around the y-intercept. Increasing the y-intercept will cause the line to move vertically up on the graph without changing the line’s slope.
b. Increasing the slope will cause the line to rotate counter-clockwise around the y-intercept. Increasing the y-intercept will cause the line to move vertically up on the graph without changing the line’s slope.
c. Increasing the slope will cause the line to rotate clockwise around the y-intercept. Increasing the y-intercept will cause the line to move horizontally right on the graph without changing the line’s slope.
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1.3 • The Language of Physics: Physical Quantities and Units

39

d. Increasing the slope will cause the line to rotate counter-clockwise around the y-intercept. Increasing the y-intercept will cause the line to move horizontally right on the graph without changing the line’s slope.

Check Your Understanding

12. Identify some advantages of metric units. a. Conversion between units is easier in metric units. b. Comparison of physical quantities is easy in metric units. c. Metric units are more modern than English units. d. Metric units are based on powers of 2.

13. The length of an American football field is

nearest

.

a.

b.

c.

d.

, excluding the end zones. How long is the field in meters? Round to the

14. The speed limit on some interstate highways is roughly ?
a. 0.1 mi/h b. 27.8 mi/h c. 62 mi/h d. 160 mi/h

. How many miles per hour is this if

is about

15. Briefly describe the target patterns for accuracy and precision and explain the differences between the two. a. Precision states how much repeated measurements generate the same or closely similar results, while accuracy states how close a measurement is to the true value of the measurement. b. Precision states how close a measurement is to the true value of the measurement, while accuracy states how much repeated measurements generate the same or closely similar result. c. Precision and accuracy are the same thing. They state how much repeated measurements generate the same or closely similar results. d. Precision and accuracy are the same thing. They state how close a measurement is to the true value of the measurement.

40 Chapter 1 • Key Terms

KEY TERMS

accuracy how close a measurement is to the correct value

for that measurement

ampere the SI unit for electrical current

atom smallest and most basic units of matter

classical physics physics, as it developed from the

Renaissance to the end of the nineteenth century

constant a quantity that does not change

conversion factor a ratio expressing how many of one unit

are equal to another unit

dependent variable the vertical, or y-axis, variable, which

changes with (or is dependent on) the value of the

independent variable

derived units units that are derived by combining the

fundamental physical units

English units (also known as the customary or imperial

system) system of measurement used in the United

States; includes units of measurement such as feet,

gallons, degrees Fahrenheit, and pounds

experiment process involved with testing a hypothesis

exponential relationship relation between variables in

which a constant change in the independent variable is

accompanied by change in the dependent variable that is

proportional to the value it already had

fundamental physical units the seven fundamental

physical units in the SI system of units are length, mass,

time, electric current, temperature, amount of a

substance, and luminous intensity

hypothesis testable statement that describes how

something in the natural world works

independent variable the horizontal, or x-axis, variable,

which is not influence by the second variable on the

graph, the dependent variable

inverse proportionality a relation between two variables

expressible by an equation of the form

where k

stays constant when x and y change; the special form of

inverse relationship that satisfies this equation

inverse relationship any relation between variables where

one variable decreases as the other variable increases

kilogram the SI unit for mass, abbreviated (kg)

linear relationships relation between variables that

produce a straight line when graphed

log-log plot a plot that uses a logarithmic scale in both axes

logarithmic scale a graphing scale in which each tick on an

axis is the previous tick multiplied by some value

meter the SI unit for length, abbreviated (m)

method of adding percents calculating the percent

uncertainty of a quantity in multiplication or division by

adding the percent uncertainties in the quantities being

added or divided

model system that is analogous to the real system of

interest in essential ways but more easily analyzed

modern physics physics as developed from the twentieth

century to the present, involving the theories of relativity

and quantum mechanics

observation step where a scientist observes a pattern or

trend within the natural world

order of magnitude the size of a quantity in terms of its

power of 10 when expressed in scientific notation

physics science aimed at describing the fundamental

aspects of our universe—energy, matter, space, motion,

and time

precision how well repeated measurements generate the

same or closely similar results

principle description of nature that is true in many, but not

all situations

quadratic relationship relation between variables that can

be expressed in the form

, which

produces a curved line when graphed

quantum mechanics major theory of modern physics which

describes the properties and nature of atoms and their

subatomic particles

science the study or knowledge of how the physical world

operates, based on objective evidence determined

through observation and experimentation

scientific law pattern in nature that is true in all

circumstances studied thus far

scientific methods techniques and processes used in the

constructing and testing of scientific hypotheses, laws,

and theories, and in deciding issues on the basis of

experiment and observation

scientific notation way of writing numbers that are too

large or small to be conveniently written in simple

decimal form; the measurement is multiplied by a power

of 10, which indicates the number of placeholder zeros in

the measurement

second the SI unit for time, abbreviated (s)

semi-log plot A plot that uses a logarithmic scale on one

axis of the graph and a linear scale on the other axis.

SI units International System of Units (SI); the

international system of units that scientists in most

countries have agreed to use; includes units such as

meters, liters, and grams; also known as the metric

system

significant figures when writing a number, the digits, or

number of digits, that express the precision of a

measuring tool used to measure the number

slope the ratio of the change of a graph on the y axis to the

change along the x-axis, the value of m in the equation of

a line,

theory explanation of patterns in nature that is supported

by much scientific evidence and verified multiple times

by various groups of researchers

theory of relativity theory constructed by Albert Einstein

which describes how space, time and energy are different

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Chapter 1 • Section Summary 41

for different observers in relative motion uncertainty a quantitative measure of how much measured
values deviate from a standard or expected value
SECTION SUMMARY
1.1 Physics: Definitions and Applications
• Physics is the most fundamental of the sciences, concerning itself with energy, matter, space and time, and their interactions.
• Modern physics involves the theory of relativity, which describes how time, space and gravity are not constant in our universe can be different for different observers, and quantum mechanics, which describes the behavior of subatomic particles.
• Physics is the basis for all other sciences, such as chemistry, biology and geology, because physics describes the fundamental way in which the universe functions.
1.2 The Scientific Methods
• Science seeks to discover and describe the underlying order and simplicity in nature.
• The processes of science include observation, hypothesis, experiment, and conclusion.
• Theories are scientific explanations that are supported by a large body experimental results.
• Scientific laws are concise descriptions of the universe that are universally true.
1.3 The Language of Physics: Physical Quantities and Units
• Physical quantities are a characteristic or property of an
KEY EQUATIONS
1.3 The Language of Physics: Physical Quantities and Units
slope intercept form
quadratic formula

universal applies throughout the known universe y-intercept the point where a plot line intersects the y-axis
object that can be measured or calculated from other measurements. • The four fundamental units we will use in this textbook are the meter (for length), the kilogram (for mass), the second (for time), and the ampere (for electric current). These units are part of the metric system, which uses powers of 10 to relate quantities over the vast ranges encountered in nature. • Unit conversions involve changing a value expressed in one type of unit to another type of unit. This is done by using conversion factors, which are ratios relating equal quantities of different units. • Accuracy of a measured value refers to how close a measurement is to the correct value. The uncertainty in a measurement is an estimate of the amount by which the measurement result may differ from this value. • Precision of measured values refers to how close the agreement is between repeated measurements. • Significant figures express the precision of a measuring tool. • When multiplying or dividing measured values, the final answer can contain only as many significant figures as the least precise value. • When adding or subtracting measured values, the final answer cannot contain more decimal places than the least precise value.
positive exponential formula
negative exponential formula

CHAPTER REVIEW
Concept Items
1.1 Physics: Definitions and Applications
1. Which statement best compares and contrasts the aims and topics of natural philosophy had versus physics?

a. Natural philosophy included all aspects of nature including physics.
b. Natural philosophy included all aspects of nature excluding physics.
c. Natural philosophy and physics are different. d. Natural philosophy and physics are essentially the

42 Chapter 1 • Chapter Review

same thing.

2. Which of the following is not an underlying assumption essential to scientific understanding? a. Characteristics of the physical universe can be perceived and objectively measured by human beings. b. Explanations of natural phenomena can be established with absolute certainty. c. Fundamental physical processes dictate how characteristics of the physical universe evolve. d. The fundamental processes of nature operate the same way everywhere and at all times.

3. Which of the following questions regarding a strain of genetically modified rice is not one that can be answered by science? a. How does the yield of the genetically modified rice compare with that of existing rice? b. Is the genetically modified rice more resistant to infestation than existing rice? c. How does the nutritional value of the genetically modified rice compare to that of existing rice? d. Should the genetically modified rice be grown commercially and sold in the marketplace?

4. What conditions imply that we can use classical physics without considering special relativity or quantum mechanics? a. 1. matter is moving at speeds of less than roughly 1 percent the speed of light, 2. objects are large enough to be seen with the naked eye, and 3. there is the involvement of a strong gravitational field.

b. 1. 2. 3.

matter is moving at speeds greater than roughly 1 percent the speed of light, objects are large enough to be seen with the naked eye, and there is the involvement of a strong gravitational field.

c. 1. 2. 3.

matter is moving at speeds of less than roughly 1 percent the speed of light, objects are too small to be seen with the naked eye, and there is the involvement of only a weak gravitational field.

d. 1. 2. 3.

matter is moving at speeds of less than roughly 1 percent the speed of light, objects are large enough to be seen with the naked eye, and there is the involvement of a weak gravitational field.

5. How could physics be useful in weather prediction? a. Physics helps in predicting how burning fossil fuel releases pollutants. b. Physics helps in predicting dynamics and movement of weather phenomena. c. Physics helps in predicting the motion of tectonic plates. d. Physics helps in predicting how the flowing water affects Earth’s surface.
6. How do physical therapists use physics while on the job? Explain. a. Physical therapists do not require knowledge of physics because their job is mainly therapy and not physics. b. Physical therapists do not require knowledge of physics because their job is more social in nature and unscientific. c. Physical therapists require knowledge of physics know about muscle contraction and release of energy. d. Physical therapists require knowledge of physics to know about chemical reactions inside the body and make decisions accordingly.
7. What is meant when a physical law is said to be universal? a. The law can explain everything in the universe. b. The law is applicable to all physical phenomena. c. The law applies everywhere in the universe. d. The law is the most basic one and all laws are derived from it.
8. What subfield of physics could describe small objects traveling at high speeds or experiencing a strong gravitational field? a. general theory of relativity b. classical physics c. quantum relativity d. special theory of relativity
9. Why is Einstein’s theory of relativity considered part of modern physics, as opposed to classical physics? a. Because it was considered less outstanding than the classics of physics, such as classical mechanics. b. Because it was popular physics enjoyed by average people today, instead of physics studied by the elite. c. Because the theory deals with very slow-moving objects and weak gravitational fields. d. Because it was among the new 19th-century discoveries that changed physics.
1.2 The Scientific Methods
10. Describe the difference between an observation and a hypothesis.

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Chapter 1 • Chapter Review 43

a. An observation is seeing what happens; a hypothesis is a testable, educated guess.
b. An observation is a hypothesis that has been confirmed.
c. Hypotheses and observations are independent of each other.
d. Hypotheses are conclusions based on some observations.
11. Describe how modeling is useful in studying the structure of the atom. a. Modeling replaces the real system by something similar but easier to examine. b. Modeling replaces the real system by something more interesting to examine. c. Modeling replaces the real system by something with more realistic properties. d. Modeling includes more details than are present in the real system.
12. How strongly is a hypothesis supported by evidence compared to a theory? a. A theory is supported by little evidence, if any, at first, while a hypothesis is supported by a large amount of available evidence. b. A hypothesis is supported by little evidence, if any, at first. A theory is supported by a large amount of available evidence. c. A hypothesis is supported by little evidence, if any, at first. A theory does not need any experiments in support. d. A theory is supported by little evidence, if any, at first. A hypothesis does not need any experiments in support.
1.3 The Language of Physics: Physical Quantities and Units
13. Which of the following does not contribute to the uncertainty? a. the limitations of the measuring device b. the skill of the person making the measurement c. the regularities in the object being measured d. other factors that affect the outcome (depending on the situation)
14. How does the independent variable in a graph differ from the dependent variable? a. The dependent variable varies linearly with the independent variable. b. The dependent variable depends on the scale of the axis chosen while independent variable does not. c. The independent variable is directly manipulated or controlled by the person doing the experiment, while dependent variable is the one that changes as

a result. d. The dependent and independent variables are fixed
by a convention and hence they are the same.

15. What could you conclude about these two lines?

1. Line A has a slope of 2. Line B has a slope of

a. Line A is a decreasing line while line B is an increasing line, with line A being much steeper than line B.
b. Line A is a decreasing line while line B is an increasing line, with line B being much steeper than line A.
c. Line B is a decreasing line while line A is an increasing line, with line A being much steeper than line B.
d. Line B is a decreasing line while line A is an increasing line, with line B being much steeper than line A.

16. Velocity, or speed, is measured using the following

formula:

where v is velocity, d is the distance

travelled, and t is the time the object took to travel the

distance. If the velocity-time data are plotted on a

graph, which variable will be on which axis? Why?

a. Time would be on the x-axis and velocity on the y-

axis, because time is an independent variable and

velocity is a dependent variable.

b. Velocity would be on the x-axis and time on the y-

axis, because time is the independent variable and

velocity is the dependent variable.

c. Time would be on the x-axis and velocity on the y-

axis, because time is a dependent variable and

velocity is a independent variable.

d. Velocity would be on x-axis and time on the y-axis,

because time is a dependent variable and velocity is

a independent variable.

17. The uncertainty of a triple-beam balance is is the percent uncertainty in a measurement of ? a. b. c. d.

. What

18. What is the definition of uncertainty? a. Uncertainty is the number of assumptions made prior to the measurement of a physical quantity. b. Uncertainty is a measure of error in a measurement due to the use of a non-calibrated instrument. c. Uncertainty is a measure of deviation of the measured value from the standard value. d. Uncertainty is a measure of error in measurement

44 Chapter 1 • Chapter Review

due to external factors like air friction and

temperature.

Critical Thinking Items
1.1 Physics: Definitions and Applications
19. In what sense does Einstein’s theory of relativity illustrate that physics describes fundamental aspects of our universe? a. It describes how speed affects different observers’ measurements of time and space. b. It describes how different parts of the universe are far apart and do not affect each other. c. It describes how people think of other people’s views from their own frame of reference. d. It describes how a frame of reference is necessary to describe position or motion.
20. Can classical physics be used to accurately describe a satellite moving at a speed of 7500 m/s? Explain why or why not. a. No, because the satellite is moving at a speed much smaller than the speed of the light and is not in a strong gravitational field. b. No, because the satellite is moving at a speed much smaller than the speed of the light and is in a strong gravitational field. c. Yes, because the satellite is moving at a speed much smaller than the speed of the light and it is not in a strong gravitational field. d. Yes, because the satellite is moving at a speed much smaller than the speed of the light and is in a strong gravitational field.
21. What would be some ways in which physics was involved in building the features of the room you are in right now? a. Physics is involved in structural strength, dimensions, etc., of the room. b. Physics is involved in the air composition inside the room. c. Physics is involved in the desk arrangement inside the room. d. Physics is involved in the behavior of living beings inside the room.
22. What theory of modern physics describes the interrelationships between space, time, speed, and gravity? a. atomic theory b. nuclear physics c. quantum mechanics d. general relativity
23. According to Einstein’s theory of relativity, how could you effectively travel many years into Earth’s future, but

not age very much yourself? a. by traveling at a speed equal to the speed of light b. by traveling at a speed faster than the speed of light c. by traveling at a speed much slower than the speed
of light d. by traveling at a speed slightly slower than the
speed of light
1.2 The Scientific Methods
24. You notice that the water level flowing in a stream near your house increases when it rains and the water turns brown. Which of these are the best hypothesis to explain why the water turns brown. Assume you have all of the means to test the contents of the stream water. a. The water in the stream turns brown because molecular forces between water molecules are stronger than mud molecules b. The water in the stream turns brown because of the breakage of a weak chemical bond with the hydrogen atom in the water molecule. c. The water in the stream turns brown because it picks up dirt from the bank as the water level increases when it rains. d. The water in the stream turns brown because the density of the water increases with increase in water level.
25. Light travels as waves at an approximate speed of 300,000,000 m/s (186,000 mi/s). Designers of devices that use mirrors and lenses model the traveling light by straight lines, or light rays. Describe why it would be useful to model the light as rays of light instead of describing them accurately as electromagnetic waves. a. A model can be constructed in such a way that the speed of light decreases. b. Studying a model makes it easier to analyze the path that the light follows. c. Studying a model will help us to visualize why light travels at such great speed. d. Modeling cannot be used to study traveling light as our eyes cannot track the motion of light.
26. A friend says that he doesn’t trust scientific explanations because they are just theories, which are basically educated guesses. What could you say to convince him that scientific theories are different from the everyday use of the word theory? a. A theory is a scientific explanation that has been repeatedly tested and supported by many experiments. b. A theory is a hypothesis that has been tested and

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Chapter 1 • Chapter Review 45

supported by some experiments. c. A theory is a set of educated guesses, but at least
one of the guesses remain true in each experiment. d. A theory is a set of scientific explanations that has
at least one experiment in support of it.
27. Give an example of a hypothesis that cannot be tested experimentally. a. The structure of any part of the broccoli is similar to the whole structure of the broccoli. b. Ghosts are the souls of people who have died. c. The average speed of air molecules increases with temperature. d. A vegetarian is less likely to be affected by night blindness.
28. Would it be possible to scientifically prove that a supreme being exists or not? Briefly explain your answer. a. It can be proved scientifically because it is a testable hypothesis. b. It cannot be proved scientifically because it is not a testable hypothesis. c. It can be proved scientifically because it is not a testable hypothesis. d. It cannot be proved scientifically because it is a testable hypothesis.

1.3 The Language of Physics: Physical Quantities and Units

29. A marathon runner completes a

course in

,

, and . There is an uncertainty of

in the distance traveled and an uncertainty of in the

elapsed time.

1. Calculate the percent uncertainty in the distance. 2. Calculate the uncertainty in the elapsed time. 3. What is the average speed in meters per second? 4. What is the uncertainty in the average speed?

a.

,

,

,

b.

,

,

,

c.

,

,

,

d.

,

,

,

30. A car engine moves a piston with a circular cross section

of

diameter a distance of

to compress the gas in the cylinder.

By what amount did the gas decrease in volume in cubic

centimeters? Find the uncertainty in this volume.

a.

b.

c.

d.

31. What would be the slope for a line passing through the two points below?

Point 1: (1, 0.1) Point 2: (7, 26.8)

a. b. c. d.

32. The sides of a small rectangular box are measured

and

long and

high. Calculate

its volume and uncertainty in cubic centimeters.

Assume the measuring device is accurate to

.

a.

b.

c.

d.

33. Calculate the approximate number of atoms in a
bacterium. Assume that the average mass of an atom in
the bacterium is ten times the mass of a hydrogen atom.
(Hint—The mass of a hydrogen atom is on the order of 10−27 kg and the mass of a bacterium is on the order of 10−15 kg .) a. 1010 atoms b. 1011 atoms c. 1012 atoms d. 1013 atoms

Problems
1.3 The Language of Physics: Physical Quantities and Units
34. A commemorative coin that sells for $40 is advertised to be plated with 15 mg of gold. Suppose gold is worth about $1,300 per ounce. Which of the following best represents the value of the gold in the coin? a. $0.33 b. $0.69

c. $3.30 d. $6.90

35. If a marathon runner runs

in one direction,

in another direction and

in a

third direction, how much distance did the runner run?

Be sure to report your answer using the proper number

of significant figures.

a.

b.

c.

46 Chapter 1 • Test Prep

d.

36. The speed limit on some interstate highways is roughly

. What is this in meters per second? How many

miles per hour is this?

a.

,

b.

,

c.

,

d.

,

37. The length and width of a rectangular room are

measured to be

by

. Calculate the area of the room and its uncertainty in

square meters.

a.

b.

c.

d.

Performance Task
1.3 The Language of Physics: Physical Quantities and Units
38. a. Create a new system of units to describe something that interests you. Your unit should be described using at least two subunits. For example, you can decide to measure the quality of songs using a new unit called song awesomeness. Song awesomeness

is measured by: the number of songs downloaded and the number of times the song was used in movies. b. Create an equation that shows how to calculate your unit. Then, using your equation, create a sample dataset that you could graph. Are your two subunits related linearly, quadratically, or inversely?

TEST PREP
Multiple Choice
1.1 Physics: Definitions and Applications
39. Modern physics could best be described as the combination of which theories? a. quantum mechanics and Einstein’s theory of relativity b. quantum mechanics and classical physics c. Newton’s laws of motion and classical physics d. Newton’s laws of motion and Einstein’s theory of relativity
40. Which of the following could be studied accurately using classical physics? a. the strength of gravity within a black hole b. the motion of a plane through the sky c. the collisions of subatomic particles d. the effect of gravity on the passage of time
41. Which of the following best describes why knowledge of physics is necessary to understand all other sciences? a. Physics explains how energy passes from one object to another. b. Physics explains how gravity works. c. Physics explains the motion of objects that can be seen with the naked eye. d. Physics explains the fundamental aspects of the universe.
42. What does radiation therapy, used to treat cancer patients, have to do with physics? a. Understanding how cells reproduce is mainly about

physics. b. Predictions of the side effects from the radiation
therapy are based on physics. c. The devices used for generating some kinds of
radiation are based on principles of physics. d. Predictions of the life expectancy of patients
receiving radiation therapy are based on physics.
1.2 The Scientific Methods
43. The free-electron model of metals explains some of the important behaviors of metals by assuming the metal’s electrons move freely through the metal without repelling one another. In what sense is the free-electron theory based on a model? a. Its use requires constructing replicas of the metal wire in the lab. b. It involves analyzing an imaginary system simpler than the real wire it resembles. c. It examines a model, or ideal, behavior that other metals should imitate. d. It attempts to examine the metal in a very realistic, or model, way.
44. A scientist wishes to study the motion of about 1,000 molecules of gas in a container by modeling them as tiny billiard balls bouncing randomly off one another. Which of the following is needed to calculate and store data on their detailed motion? a. a group of hypotheses that cannot be practically tested in real life

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Chapter 1 • Test Prep 47

b. a computer that can store and perform calculations on large data sets
c. a large amount of experimental results on the molecules and their motion
d. a collection of hypotheses that have not yet been tested regarding the molecules
45. When a large body of experimental evidence supports a hypothesis, what may the hypothesis eventually be considered? a. observation b. insight c. conclusion d. law
46. While watching some ants outside of your house, you notice that the worker ants gather in a specific area on your lawn. Which of the following is a testable hypothesis that attempts to explain why the ants gather in that specific area on the lawn. a. The worker thought it was a nice location. b. because ants may have to find a spot for the queen to lay eggs c. because there may be some food particles lying there d. because the worker ants are supposed to group together at a place.
1.3 The Language of Physics: Physical Quantities and Units
47. Which of the following would describe a length that is of a meter?
a. kilometers b. megameters

c. millimeters d. micrometers
48. Suppose that a bathroom scale reads a person’s mass as 65 kg with a 3 percent uncertainty. What is the uncertainty in their mass in kilograms? a. a. 2 kg b. b. 98 kg c. c. 5 kg d. d. 0
49. Which of the following best describes a variable? a. a trend that shows an exponential relationship b. something whose value can change over multiple measurements c. a measure of how much a plot line changes along the y-axis d. something that remains constant over multiple measurements
50. A high school track coach has just purchased a new stopwatch that has an uncertainty of ±0.05 s . Runners on the team regularly clock 100-m sprints in 12.49 s to 15.01 s . At the school’s last track meet, the first-place sprinter came in at 12.04 s and the second-place sprinter came in at 12.07 s . Will the coach’s new stopwatch be helpful in timing the sprint team? Why or why not? a. No, the uncertainty in the stopwatch is too large to effectively differentiate between the sprint times. b. No, the uncertainty in the stopwatch is too small to effectively differentiate between the sprint times. c. Yes, the uncertainty in the stopwatch is too large to effectively differentiate between the sprint times. d. Yes, the uncertainty in the stopwatch is too small to effectively differentiate between the sprint times.

Short Answer
1.1 Physics: Definitions and Applications
51. Describe the aims of physics. a. Physics aims to explain the fundamental aspects of our universe and how these aspects interact with one another. b. Physics aims to explain the biological aspects of our universe and how these aspects interact with one another. c. Physics aims to explain the composition, structure and changes in matter occurring in the universe. d. Physics aims to explain the social behavior of living beings in the universe.
52. Define the fields of magnetism and electricity and state how are they are related. a. Magnetism describes the attractive force between a

magnetized object and a metal like iron. Electricity involves the study of electric charges and their movements. Magnetism is not related to the electricity. b. Magnetism describes the attractive force between a magnetized object and a metal like iron. Electricity involves the study of electric charges and their movements. Magnetism is produced by a flow electrical charges. c. Magnetism involves the study of electric charges and their movements. Electricity describes the attractive force between a magnetized object and a metal. Magnetism is not related to the electricity. d. Magnetism involves the study of electric charges and their movements. Electricity describes the attractive force between a magnetized object and a metal. Magnetism is produced by the flow electrical charges.

48 Chapter 1 • Test Prep

53. Describe what two topics physicists are trying to unify with relativistic quantum mechanics. How will this unification create a greater understanding of our universe? a. Relativistic quantum mechanics unifies quantum mechanics with Einstein’s theory of relativity. The unified theory creates a greater understanding of our universe because it can explain objects of all sizes and masses. b. Relativistic quantum mechanics unifies classical mechanics with Einstein’s theory of relativity. The unified theory creates a greater understanding of our universe because it can explain objects of all sizes and masses. c. Relativistic quantum mechanics unifies quantum mechanics with Einstein’s theory of relativity. The unified theory creates a greater understanding of our universe because it is unable to explain objects of all sizes and masses. d. Relativistic quantum mechanics unifies classical mechanics with the Einstein’s theory of relativity. The unified theory creates a greater understanding of our universe because it is unable to explain objects of all sizes and masses.
54. The findings of studies in quantum mechanics have been described as strange or weird compared to those of classical physics. Explain why this would be so. a. It is because the phenomena it explains are outside the normal range of human experience which deals with much larger objects. b. It is because the phenomena it explains can be perceived easily, namely, ordinary-sized objects. c. It is because the phenomena it explains are outside the normal range of human experience, namely, the very large and the very fast objects. d. It is because the phenomena it explains can be perceived easily, namely, the very large and the very fast objects.
55. How could knowledge of physics help you find a faster way to drive from your house to your school? a. Physics can explain the traffic on a particular street and help us know about the traffic in advance. b. Physics can explain about the ongoing construction of roads on a particular street and help us know about delays in the traffic in advance. c. Physics can explain distances, speed limits on a particular street and help us categorize faster routes. d. Physics can explain the closing of a particular street and help us categorize faster routes.
56. How could knowledge of physics help you build a sound and energy-efficient house?

a. An understanding of force, pressure, heat, electricity, etc., which all involve physics, will help me design a sound and energy-efficient house.
b. An understanding of the air composition, chemical composition of matter, etc., which all involves physics, will help me design a sound and energyefficient house.
c. An understanding of material cost and economic factors involving physics will help me design a sound and energy-efficient house.
d. An understanding of geographical location and social environment which involves physics will help me design a sound and energy-efficient house.
57. What aspects of physics would a chemist likely study in trying to discover a new chemical reaction? a. Physics is involved in understanding whether the reactants and products dissolve in water. b. Physics is involved in understanding the amount of energy released or required in a chemical reaction. c. Physics is involved in what the products of the reaction will be. d. Physics is involved in understanding the types of ions produced in a chemical reaction.
1.2 The Scientific Methods
58. You notice that it takes more force to get a large box to start sliding across the floor than it takes to get the box sliding faster once it is already moving. Create a testable hypothesis that attempts to explain this observation. a. The floor has greater distortions of space-time for moving the sliding box faster than for the box at rest. b. The floor has greater distortions of space-time for the box at rest than for the sliding box. c. The resistance between the floor and the box is less when the box is sliding then when the box is at rest. d. The floor dislikes having objects move across it and therefore holds the box rigidly in place until it cannot resist the force.
59. Design an experiment that will test the following hypothesis: driving on a gravel road causes greater damage to a car than driving on a dirt road. a. To test the hypothesis, compare the damage to the car by driving it on a smooth road and a gravel road. b. To test the hypothesis, compare the damage to the car by driving it on a smooth road and a dirt road. c. To test the hypothesis, compare the damage to the car by driving it on a gravel road and the dirt road. d. This is not a testable hypothesis.
60. How is a physical model, such as a spherical mass held

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Chapter 1 • Test Prep 49

in place by springs, used to represent an atom vibrating in a solid, similar to a computer-based model, such as that predicting how gravity affects the orbits of the planets? a. Both a physical model and a computer-based
model should be built around a hypothesis and could be able to test the hypothesis. b. Both a physical model and a computer-based model should be built around a hypothesis but they cannot be used to test the hypothesis. c. Both a physical model and a computer-based model should be built around the results of scientific studies and could be used to make predictions about the system under study. d. Both a physical model and a computer-based model should be built around the results of scientific studies but cannot be used to make predictions about the system under study.
61. Explain the advantages and disadvantages of using a model to predict a life-or-death situation, such as whether or not an asteroid will strike Earth. a. The advantage of using a model is that it provides predictions quickly, but the disadvantage of using a model is that it could make erroneous predictions. b. The advantage of using a model is that it provides accurate predictions, but the disadvantage of using a model is that it takes a long time to make predictions. c. The advantage of using a model is that it provides predictions quickly without any error. There are no disadvantages of using a scientific model. d. The disadvantage of using models is that it takes longer time to make predictions and the predictions are inaccurate. There are no advantages to using a scientific model.
62. A friend tells you that a scientific law cannot be changed. State whether or not your friend is correct and then briefly explain your answer. a. Correct, because laws are theories that have been proved true. b. Correct, because theories are laws that have been proved true. c. Incorrect, because a law is changed if new evidence contradicts it. d. Incorrect, because a law is changed when a theory contradicts it.
63. How does a scientific law compare to a local law, such as that governing parking at your school, in terms of whether or not laws can be changed, and how universal a law is? a. A local law applies only in a specific area, but a

scientific law is applicable throughout the universe. Both the local law and the scientific law can change. b. A local law applies only in a specific area, but a scientific law is applicable throughout the universe. A local law can change, but a scientific law cannot be changed. c. A local law applies throughout the universe but a scientific law is applicable only in a specific area. Both the local and the scientific law can change. d. A local law applies throughout the universe, but a scientific law is applicable only in a specific area. A local law can change, but a scientific law cannot be changed.
64. Can the validity of a model be limited, or must it be universally valid? How does this compare to the required validity of a theory or a law? a. Models, theories and laws must be universally valid. b. Models, theories, and laws have only limited validity. c. Models have limited validity while theories and laws are universally valid. d. Models and theories have limited validity while laws are universally valid.

1.3 The Language of Physics: Physical Quantities and Units

65. The speed of sound is measured at

on a certain

day. What is this in

? Report your answer in

scientific notation.

a.

b.

c.

d.

66. Describe the main difference between the metric system and the U.S. Customary System. a. In the metric system, unit changes are based on powers of 10, while in the U.S. customary system, each unit conversion has unrelated conversion factors. b. In the metric system, each unit conversion has unrelated conversion factors, while in the U.S. customary system, unit changes are based on powers of 10. c. In the metric system, unit changes are based on powers of 2, while in the U.S. customary system, each unit conversion has unrelated conversion factors. d. In the metric system, each unit conversion has unrelated conversion factors, while in the U.S. customary system, unit changes are based on

50 Chapter 1 • Test Prep

powers of 2.
67. An infant’s pulse rate is measured to be . What is the percent uncertainty in
this measurement? a. b. c. d.
68. Explain how the uncertainty of a measurement relates to the accuracy and precision of the measuring device. Include the definitions of accuracy and precision in your answer. a. A decrease in the precision of a measurement increases the uncertainty of the measurement, while a decrease in accuracy does not. b. A decrease in either the precision or accuracy of a measurement increases the uncertainty of the measurement. c. An increase in either the precision or accuracy of a measurement will increase the uncertainty of that measurement. d. An increase in the accuracy of a measurement will increase the uncertainty of that measurement, while an increase in precision will not.
69. Describe all of the characteristics that can be determined about a straight line with a slope of and a y-intercept of on a graph. a. Based on the information, the line has a negative slope. Because its y-intercept is 50 and its slope is negative, this line gradually rises on the graph as the x-value increases. b. Based on the information, the line has a negative slope. Because its y-intercept is 50 and its slope is negative, this line gradually moves downward on

the graph as the x-value increases. c. Based on the information, the line has a positive
slope. Because its y-intercept is 50 and its slope is positive, this line gradually rises on the graph as the x-value increases. d. Based on the information, the line has a positive slope. Because its y-intercept is 50 and its slope is positive, this line gradually moves downward on the graph as the x-value increases. 70. The graph shows the temperature change over time of a heated cup of water.
What is the slope of the graph between the time period 2 min and 5 min? a. –15 ºC/min b. –0.07 ºC/min c. 0.07 ºC/min d. 15 ºC/min

Extended Response
1.2 The Scientific Methods
71. You wish to perform an experiment on the stopping distance of your new car. Create a specific experiment to measure the distance. Be sure to specifically state how you will set up and take data during your experiment. a. Drive the car at exactly 50 mph and then press harder on the accelerator pedal until the velocity reaches the speed 60 mph and record the distance this takes. b. Drive the car at exactly 50 mph and then apply the brakes until it stops and record the distance this takes. c. Drive the car at exactly 50 mph and then apply the brakes until it stops and record the time it takes.

d. Drive the car at exactly 50 mph and then apply the accelerator until it reaches the speed of 60 mph and record the time it takes.
72. You wish to make a model showing how traffic flows around your city or local area. Describe the steps you would take to construct your model as well as some hypotheses that your model could test and the model’s limitations in terms of what could not be tested. a. 1. Testable hypotheses like the gravitational pull on each vehicle while in motion and the average speed of vehicles is 40 mph 2. Non-testable hypotheses like the average number of vehicles passing is 935 per day and carbon emission from each of the moving vehicle

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Chapter 1 • Test Prep 51

b. 1. 2.

Testable hypotheses like the average number of vehicles passing is 935 per day and the average speed of vehicles is 40 mph Non-testable hypotheses like the gravitational pull on each vehicle while in motion and the carbon emission from each of the moving vehicle

c. 1. 2.

Testable hypotheses like the average number of vehicles passing is 935 per day and the carbon emission from each of the moving vehicle Non-testable hypotheses like the gravitational pull on each vehicle while in motion and the average speed of the vehicles is 40 mph

d. 1. 2.

Testable hypotheses like the average number of vehicles passing is 935 per day and the gravitational pull on each vehicle while in motion Non-testable hypotheses like the average speed of vehicles is 40 mph and the carbon emission from each of the moving vehicle

73. What would play the most important role in leading to an experiment in the scientific world becoming a scientific law? a. Further testing would need to show it is a universally followed rule. b. The observation would have to be described in a

published scientific article. c. The experiment would have to be repeated once or
twice. d. The observer would need to be a well-known
scientist whose authority was accepted.

1.3 The Language of Physics: Physical Quantities and Units

74. Tectonic plates are large segments of the Earth’s crust

that move slowly. Suppose that one such plate has an

average speed of

. What distance does it

move in at this speed? What is its speed in

kilometers per million years? Report all of your answers

using scientific notation.

a.

b.

c.

d.

75. At x = 3, a function f(x) has a positive value, with a positive slope that is decreasing in magnitude with increasing x. Which option could correspond to f(x)? a. b. c. d.

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CHAPTER 2
Motion in One Dimension
Figure 2.1 Shanghai Maglev. At this rate, a train traveling from Boston to Washington, DC, a distance of 439 miles, could make the trip in under an hour and a half. Presently, the fastest train on this route takes over six hours to cover this distance. (Alex Needham, Public Domain)
Chapter Outline
2.1 Relative Motion, Distance, and Displacement 2.2 Speed and Velocity 2.3 Position vs. Time Graphs 2.4 Velocity vs. Time Graphs INTRODUCTION Unless you have flown in an airplane, you have probably never traveled faster than 150 mph. Can you imagine traveling in a train like the one shown in Figure 2.1 that goes over 300 mph? Despite the high speed, the people riding in this train may not notice that they are moving at all unless they look out the window! This is because motion, even motion at 300 mph, is relative to the observer. In this chapter, you will learn why it is important to identify a reference frame in order to clearly describe motion. For now, the motion you describe will be one-dimensional. Within this context, you will learn the difference between distance and displacement as well as the difference between speed and velocity. Then you will look at some graphing and problem-solving techniques.

54

Chapter 2 • Motion in One Dimension

2.1 Relative Motion, Distance, and Displacement
Section Learning Objectives By the end of this section, you will be able to do the following:
• Describe motion in different reference frames • Define distance and displacement, and distinguish between the two • Solve problems involving distance and displacement
Section Key Terms

displacement distance

kinematics magnitude

position

reference frame scalar

vector

Defining Motion
Our study of physics opens with kinematics—the study of motion without considering its causes. Objects are in motion everywhere you look. Everything from a tennis game to a space-probe flyby of the planet Neptune involves motion. When you are resting, your heart moves blood through your veins. Even in inanimate objects, atoms are always moving.
How do you know something is moving? The location of an object at any particular time is its position. More precisely, you need to specify its position relative to a convenient reference frame. Earth is often used as a reference frame, and we often describe the position of an object as it relates to stationary objects in that reference frame. For example, a rocket launch would be described in terms of the position of the rocket with respect to Earth as a whole, while a professor’s position could be described in terms of where she is in relation to the nearby white board. In other cases, we use reference frames that are not stationary but are in motion relative to Earth. To describe the position of a person in an airplane, for example, we use the airplane, not Earth, as the reference frame. (See Figure 2.2.) Thus, you can only know how fast and in what direction an object's position is changing against a background of something else that is either not moving or moving with a known speed and direction. The reference frame is the coordinate system from which the positions of objects are described.

Figure 2.2 Are clouds a useful reference frame for airplane passengers? Why or why not? (Paul Brennan, Public Domain)
Your classroom can be used as a reference frame. In the classroom, the walls are not moving. Your motion as you walk to the door, can be measured against the stationary background of the classroom walls. You can also tell if other things in the classroom are moving, such as your classmates entering the classroom or a book falling off a desk. You can also tell in what direction something is moving in the classroom. You might say, “The teacher is moving toward the door.” Your reference frame allows you to determine not only that something is moving but also the direction of motion.
You could also serve as a reference frame for others’ movement. If you remained seated as your classmates left the room, you would measure their movement away from your stationary location. If you and your classmates left the room together, then your perspective of their motion would be change. You, as the reference frame, would be moving in the same direction as your other moving classmates. As you will learn in the Snap Lab, your description of motion can be quite different when viewed from different reference frames.
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2.1 • Relative Motion, Distance, and Displacement

55

Snap Lab
Looking at Motion from Two Reference Frames
In this activity you will look at motion from two reference frames. Which reference frame is correct?
• Choose an open location with lots of space to spread out so there is less chance of tripping or falling due to a collision and/or loose basketballs.
• 1 basketball
Procedure 1. Work with a partner. Stand a couple of meters away from your partner. Have your partner turn to the side so that you
are looking at your partner’s profile. Have your partner begin bouncing the basketball while standing in place. Describe the motion of the ball. 2. Next, have your partner again bounce the ball, but this time your partner should walk forward with the bouncing ball. You will remain stationary. Describe the ball's motion. 3. Again have your partner walk forward with the bouncing ball. This time, you should move alongside your partner while continuing to view your partner’s profile. Describe the ball's motion. 4. Switch places with your partner, and repeat Steps 1–3.
GRASP CHECK
How do the different reference frames affect how you describe the motion of the ball? a. The motion of the ball is independent of the reference frame and is same for different reference frames. b. The motion of the ball is independent of the reference frame and is different for different reference frames. c. The motion of the ball is dependent on the reference frame and is same for different reference frames. d. The motion of the ball is dependent on the reference frames and is different for different reference frames.

LINKS TO PHYSICS History: Galileo's Ship

Figure 2.3 Galileo Galilei (1564–1642) studied motion and developed the concept of a reference frame. (Domenico Tintoretto)
The idea that a description of motion depends on the reference frame of the observer has been known for hundreds of years. The 17th-century astronomer Galileo Galilei (Figure 2.3) was one of the first scientists to explore this idea. Galileo suggested the following thought experiment: Imagine a windowless ship moving at a constant speed and direction along a perfectly calm sea. Is there a way that a person inside the ship can determine whether the ship is moving? You can extend this thought experiment

56

Chapter 2 • Motion in One Dimension

by also imagining a person standing on the shore. How can a person on the shore determine whether the ship is moving?
Galileo came to an amazing conclusion. Only by looking at each other can a person in the ship or a person on shore describe the motion of one relative to the other. In addition, their descriptions of motion would be identical. A person inside the ship would describe the person on the land as moving past the ship. The person on shore would describe the ship and the person inside it as moving past. Galileo realized that observers moving at a constant speed and direction relative to each other describe motion in the same way. Galileo had discovered that a description of motion is only meaningful if you specify a reference frame.
GRASP CHECK Imagine standing on a platform watching a train pass by. According to Galileo’s conclusions, how would your description of motion and the description of motion by a person riding on the train compare? a. I would see the train as moving past me, and a person on the train would see me as stationary. b. I would see the train as moving past me, and a person on the train would see me as moving past the train. c. I would see the train as stationary, and a person on the train would see me as moving past the train. d. I would see the train as stationary, and a person on the train would also see me as stationary.

Distance vs. Displacement
As we study the motion of objects, we must first be able to describe the object’s position. Before your parent drives you to school, the car is sitting in your driveway. Your driveway is the starting position for the car. When you reach your high school, the car has changed position. Its new position is your school.

Figure 2.4 Your total change in position is measured from your house to your school.
Physicists use variables to represent terms. We will use d to represent car’s position. We will use a subscript to differentiate between the initial position, d0, and the final position, df. In addition, vectors, which we will discuss later, will be in bold or will have an arrow above the variable. Scalars will be italicized.
TIPS FOR SUCCESS
In some books, x or s is used instead of d to describe position. In d0, said d naught, the subscript 0 stands for initial. When we begin to talk about two-dimensional motion, sometimes other subscripts will be used to describe horizontal position, dx, or vertical position, dy. So, you might see references to d0x and dfy.
Now imagine driving from your house to a friend's house located several kilometers away. How far would you drive? The distance an object moves is the length of the path between its initial position and its final position. The distance you drive to your friend's house depends on your path. As shown in Figure 2.5, distance is different from the length of a straight line between two points. The distance you drive to your friend's house is probably longer than the straight line between the two houses.
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2.1 • Relative Motion, Distance, and Displacement

57

Figure 2.5 A short line separates the starting and ending points of this motion, but the distance along the path of motion is considerably longer.
We often want to be more precise when we talk about position. The description of an object’s motion often includes more than just the distance it moves. For instance, if it is a five kilometer drive to school, the distance traveled is 5 kilometers. After dropping you off at school and driving back home, your parent will have traveled a total distance of 10 kilometers. The car and your parent will end up in the same starting position in space. The net change in position of an object is its displacement, or
The Greek letter delta, , means change in.
Figure 2.6 The total distance that your car travels is 10 km, but the total displacement is 0.
Snap Lab Distance vs. Displacement
In this activity you will compare distance and displacement. Which term is more useful when making measurements? • 1 recorded song available on a portable device • 1 tape measure • 3 pieces of masking tape • A room (like a gym) with a wall that is large and clear enough for all pairs of students to walk back and forth without running into each other.
Procedure 1. One student from each pair should stand with their back to the longest wall in the classroom. Students should stand at
least 0.5 meters away from each other. Mark this starting point with a piece of masking tape. 2. The second student from each pair should stand facing their partner, about two to three meters away. Mark this point

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Chapter 2 • Motion in One Dimension

with a second piece of masking tape. 3. Student pairs line up at the starting point along the wall. 4. The teacher turns on the music. Each pair walks back and forth from the wall to the second marked point until the
music stops playing. Keep count of the number of times you walk across the floor. 5. When the music stops, mark your ending position with the third piece of masking tape. 6. Measure from your starting, initial position to your ending, final position. 7. Measure the length of your path from the starting position to the second marked position. Multiply this measurement
by the total number of times you walked across the floor. Then add this number to your measurement from step 6. 8. Compare the two measurements from steps 6 and 7.
GRASP CHECK
1. Which measurement is your total distance traveled? 2. Which measurement is your displacement? 3. When might you want to use one over the other?
a. Measurement of the total length of your path from the starting position to the final position gives the distance traveled, and the measurement from your initial position to your final position is the displacement. Use distance to describe the total path between starting and ending points,and use displacement to describe the shortest path between starting and ending points.
b. Measurement of the total length of your path from the starting position to the final position is distance traveled, and the measurement from your initial position to your final position is displacement. Use distance to describe the shortest path between starting and ending points, and use displacement to describe the total path between starting and ending points.
c. Measurement from your initial position to your final position is distance traveled, and the measurement of the total length of your path from the starting position to the final position is displacement. Use distance to describe the total path between starting and ending points, and use displacement to describe the shortest path between starting and ending points.
d. Measurement from your initial position to your final position is distance traveled, and the measurement of the total length of your path from the starting position to the final position is displacement. Use distance to describe the shortest path between starting and ending points, and use displacement to describe the total path between starting and ending points.

If you are describing only your drive to school, then the distance traveled and the displacement are the same—5 kilometers. When you are describing the entire round trip, distance and displacement are different. When you describe distance, you only include the magnitude, the size or amount, of the distance traveled. However, when you describe the displacement, you take into account both the magnitude of the change in position and the direction of movement.
In our previous example, the car travels a total of 10 kilometers, but it drives five of those kilometers forward toward school and five of those kilometers back in the opposite direction. If we ascribe the forward direction a positive (+) and the opposite direction a negative (–), then the two quantities will cancel each other out when added together.
A quantity, such as distance, that has magnitude (i.e., how big or how much) but does not take into account direction is called a scalar. A quantity, such as displacement, that has both magnitude and direction is called a vector.
WATCH PHYSICS
Vectors & Scalars
This video (http://openstax.org/l/28vectorscalar) introduces and differentiates between vectors and scalars. It also introduces quantities that we will be working with during the study of kinematics.
Click to view content (https://www.khanacademy.org/embed_video?v=ihNZlp7iUHE)

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2.1 • Relative Motion, Distance, and Displacement

59

GRASP CHECK How does this video (https://www.khanacademy.org/science/ap-physics-1/ap-one-dimensional-motion/ap-physicsfoundations/v/introduction-to-vectors-and-scalars) help you understand the difference between distance and displacement? Describe the differences between vectors and scalars using physical quantities as examples. a. It explains that distance is a vector and direction is important, whereas displacement is a scalar and it has no direction
attached to it. b. It explains that distance is a scalar and direction is important, whereas displacement is a vector and it has no direction
attached to it. c. It explains that distance is a scalar and it has no direction attached to it, whereas displacement is a vector and direction
is important. d. It explains that both distance and displacement are scalar and no directions are attached to them.

Displacement Problems Hopefully you now understand the conceptual difference between distance and displacement. Understanding concepts is half the battle in physics. The other half is math. A stumbling block to new physics students is trying to wade through the math of physics while also trying to understand the associated concepts. This struggle may lead to misconceptions and answers that make no sense. Once the concept is mastered, the math is far less confusing.
So let’s review and see if we can make sense of displacement in terms of numbers and equations. You can calculate an object's displacement by subtracting its original position, d0, from its final position df. In math terms that means

If the final position is the same as the initial position, then

.

To assign numbers and/or direction to these quantities, we need to define an axis with a positive and a negative direction. We also need to define an origin, or O. In Figure 2.6, the axis is in a straight line with home at zero and school in the positive direction. If we left home and drove the opposite way from school, motion would have been in the negative direction. We would have assigned it a negative value. In the round-trip drive, df and d0 were both at zero kilometers. In the one way trip to school, df was at 5 kilometers and d0 was at zero km. So, was 5 kilometers.

TIPS FOR SUCCESS
You may place your origin wherever you would like. You have to make sure that you calculate all distances consistently from your zero and you define one direction as positive and the other as negative. Therefore, it makes sense to choose the easiest axis, direction, and zero. In the example above, we took home to be zero because it allowed us to avoid having to interpret a solution with a negative sign.

WORKED EXAMPLE
Calculating Distance and Displacement
A cyclist rides 3 km west and then turns around and rides 2 km east. (a) What is her displacement? (b) What distance does she ride? (c) What is the magnitude of her displacement?

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Strategy To solve this problem, we need to find the difference between the final position and the initial position while taking care to note the direction on the axis. The final position is the sum of the two displacements, and .

Solution

a. Displacement: The rider’s displacement is

.

b. Distance: The distance traveled is 3 km + 2 km = 5 km.

c. The magnitude of the displacement is 1 km.

Discussion The displacement is negative because we chose east to be positive and west to be negative. We could also have described the displacement as 1 km west. When calculating displacement, the direction mattered, but when calculating distance, the direction did not matter. The problem would work the same way if the problem were in the north–south or y-direction.

TIPS FOR SUCCESS Physicists like to use standard units so it is easier to compare notes. The standard units for calculations are called SI units (International System of Units). SI units are based on the metric system. The SI unit for displacement is the meter (m), but sometimes you will see a problem with kilometers, miles, feet, or other units of length. If one unit in a problem is an SI unit and another is not, you will need to convert all of your quantities to the same system before you can carry out the calculation.

Practice Problems
1. On an axis in which moving from right to left is positive, what is the displacement and distance of a student who walks 32 m to the right and then 17 m to the left? a. Displacement is -15 m and distance is -49 m. b. Displacement is -15 m and distance is 49 m. c. Displacement is 15 m and distance is -49 m. d. Displacement is 15 m and distance is 49 m.
2. Tiana jogs 1.5 km along a straight path and then turns and jogs 2.4 km in the opposite direction. She then turns back and jogs 0.7 km in the original direction. Let Tiana’s original direction be the positive direction. What are the displacement and distance she jogged? a. Displacement is 4.6 km,and distance is -0.2 km. b. Displacement is -0.2 km, and distance is 4.6 km. c. Displacement is 4.6 km, and distance is +0.2 km. d. Displacement is +0.2 km, and distance is 4.6 km.
WORK IN PHYSICS
Mars Probe Explosion

Figure 2.7 The Mars Climate Orbiter disaster illustrates the importance of using the correct calculations in physics. (NASA) Access for free at openstax.org.

2.1 • Relative Motion, Distance, and Displacement

61

Physicists make calculations all the time, but they do not always get the right answers. In 1998, NASA, the National Aeronautics and Space Administration, launched the Mars Climate Orbiter, shown in Figure 2.7, a $125-million-dollar satellite designed to monitor the Martian atmosphere. It was supposed to orbit the planet and take readings from a safe distance. The American scientists made calculations in English units (feet, inches, pounds, etc.) and forgot to convert their answers to the standard metric SI units. This was a very costly mistake. Instead of orbiting the planet as planned, the Mars Climate Orbiter ended up flying into the Martian atmosphere. The probe disintegrated. It was one of the biggest embarrassments in NASA’s history.
GRASP CHECK In 1999 the Mars Climate Orbiter crashed because calculation were performed in English units instead of SI units. At one point the orbiter was just 187,000 feet above the surface, which was too close to stay in orbit. What was the height of the orbiter at this time in kilometers? (Assume 1 meter equals 3.281 feet.) a. 16 km b. 18 km c. 57 km d. 614 km

Check Your Understanding
3. What does it mean when motion is described as relative? a. It means that motion of any object is described relative to the motion of Earth. b. It means that motion of any object is described relative to the motion of any other object. c. It means that motion is independent of the frame of reference. d. It means that motion depends on the frame of reference selected.
4. If you and a friend are standing side-by-side watching a soccer game, would you both view the motion from the same reference frame? a. Yes, we would both view the motion from the same reference point because both of us are at rest in Earth’s frame of reference. b. Yes, we would both view the motion from the same reference point because both of us are observing the motion from two points on the same straight line. c. No, we would both view the motion from different reference points because motion is viewed from two different points; the reference frames are similar but not the same. d. No, we would both view the motion from different reference points because response times may be different; so, the motion observed by both of us would be different.
5. What is the difference between distance and displacement? a. Distance has both magnitude and direction, while displacement has magnitude but no direction. b. Distance has magnitude but no direction, while displacement has both magnitude and direction. c. Distance has magnitude but no direction, while displacement has only direction. d. There is no difference. Both distance and displacement have magnitude and direction.
6. Which situation correctly identifies a race car’s distance traveled and the magnitude of displacement during a one-lap car race? a. The perimeter of the race track is the distance, and the shortest distance between the start line and the finish line is the magnitude of displacement. b. The perimeter of the race track is the magnitude of displacement, and the shortest distance between the start and finish line is the distance. c. The perimeter of the race track is both the distance and magnitude of displacement. d. The shortest distance between the start line and the finish line is both the distance and magnitude of displacement.
7. Why is it important to specify a reference frame when describing motion? a. Because Earth is continuously in motion; an object at rest on Earth will be in motion when viewed from outer space. b. Because the position of a moving object can be defined only when there is a fixed reference frame.

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c. Because motion is a relative term; it appears differently when viewed from different reference frames. d. Because motion is always described in Earth’s frame of reference; if another frame is used, it has to be specified with
each situation.
2.2 Speed and Velocity
Section Learning Objectives By the end of this section, you will be able to do the following:
• Calculate the average speed of an object • Relate displacement and average velocity
Section Key Terms

average speed

average velocity instantaneous speed

instantaneous velocity speed

velocity

Speed
There is more to motion than distance and displacement. Questions such as, “How long does a foot race take?” and “What was the runner’s speed?” cannot be answered without an understanding of other concepts. In this section we will look at time, speed, and velocity to expand our understanding of motion.
A description of how fast or slow an object moves is its speed. Speed is the rate at which an object changes its location. Like distance, speed is a scalar because it has a magnitude but not a direction. Because speed is a rate, it depends on the time interval of motion. You can calculate the elapsed time or the change in time, , of motion as the difference between the ending time and the beginning time

The SI unit of time is the second (s), and the SI unit of speed is meters per second (m/s), but sometimes kilometers per hour (km/h), miles per hour (mph) or other units of speed are used.
When you describe an object's speed, you often describe the average over a time period. Average speed, vavg, is the distance traveled divided by the time during which the motion occurs.

You can, of course, rearrange the equation to solve for either distance or time

Suppose, for example, a car travels 150 kilometers in 3.2 hours. Its average speed for the trip is

A car's speed would likely increase and decrease many times over a 3.2 hour trip. Its speed at a specific instant in time, however, is its instantaneous speed. A car's speedometer describes its instantaneous speed.

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63

Figure 2.8 During a 30-minute round trip to the store, the total distance traveled is 6 km. The average speed is 12 km/h. The displacement for the round trip is zero, because there was no net change in position.
WORKED EXAMPLE
Calculating Average Speed
A marble rolls 5.2 m in 1.8 s. What was the marble's average speed? Strategy We know the distance the marble travels, 5.2 m, and the time interval, 1.8 s. We can use these values in the average speed equation.
Solution
Discussion Average speed is a scalar, so we do not include direction in the answer. We can check the reasonableness of the answer by estimating: 5 meters divided by 2 seconds is 2.5 m/s. Since 2.5 m/s is close to 2.9 m/s, the answer is reasonable. This is about the speed of a brisk walk, so it also makes sense.
Practice Problems
8. A pitcher throws a baseball from the pitcher’s mound to home plate in 0.46 s. The distance is 18.4 m. What was the average speed of the baseball? a. 40 m/s b. - 40 m/s c. 0.03 m/s d. 8.5 m/s
9. Cassie walked to her friend’s house with an average speed of 1.40 m/s. The distance between the houses is 205 m. How long did the trip take her? a. 146 s b. 0.01 s c. 2.50 min d. 287 s
Velocity
The vector version of speed is velocity. Velocity describes the speed and direction of an object. As with speed, it is useful to describe either the average velocity over a time period or the velocity at a specific moment. Average velocity is displacement divided by the time over which the displacement occurs.

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Velocity, like speed, has SI units of meters per second (m/s), but because it is a vector, you must also include a direction. Furthermore, the variable v for velocity is bold because it is a vector, which is in contrast to the variable v for speed which is italicized because it is a scalar quantity.
TIPS FOR SUCCESS
It is important to keep in mind that the average speed is not the same thing as the average velocity without its direction. Like we saw with displacement and distance in the last section, changes in direction over a time interval have a bigger effect on speed and velocity.
Suppose a passenger moved toward the back of a plane with an average velocity of –4 m/s. We cannot tell from the average velocity whether the passenger stopped momentarily or backed up before he got to the back of the plane. To get more details, we must consider smaller segments of the trip over smaller time intervals such as those shown in Figure 2.9. If you consider infinitesimally small intervals, you can define instantaneous velocity, which is the velocity at a specific instant in time. Instantaneous velocity and average velocity are the same if the velocity is constant.

Figure 2.9 The diagram shows a more detailed record of an airplane passenger heading toward the back of the plane, showing smaller segments of his trip.
Earlier, you have read that distance traveled can be different than the magnitude of displacement. In the same way, speed can be different than the magnitude of velocity. For example, you drive to a store and return home in half an hour. If your car’s odometer shows the total distance traveled was 6 km, then your average speed was 12 km/h. Your average velocity, however, was zero because your displacement for the round trip is zero.
WATCH PHYSICS Calculating Average Velocity or Speed
This video (http://openstax.org/l/28avgvelocity) reviews vectors and scalars and describes how to calculate average velocity and average speed when you know displacement and change in time. The video also reviews how to convert km/h to m/s. Click to view content (https://www.khanacademy.org/embed_video?v=MAS6mBRZZXA)
GRASP CHECK Which of the following fully describes a vector and a scalar quantity and correctly provides an example of each?
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65

a. A scalar quantity is fully described by its magnitude, while a vector needs both magnitude and direction to fully describe it. Displacement is an example of a scalar quantity and time is an example of a vector quantity.
b. A scalar quantity is fully described by its magnitude, while a vector needs both magnitude and direction to fully describe it. Time is an example of a scalar quantity and displacement is an example of a vector quantity.
c. A scalar quantity is fully described by its magnitude and direction, while a vector needs only magnitude to fully describe it. Displacement is an example of a scalar quantity and time is an example of a vector quantity.
d. A scalar quantity is fully described by its magnitude and direction, while a vector needs only magnitude to fully describe it. Time is an example of a scalar quantity and displacement is an example of a vector quantity.

WORKED EXAMPLE
Calculating Average Velocity
A student has a displacement of 304 m north in 180 s. What was the student's average velocity? Strategy We know that the displacement is 304 m north and the time is 180 s. We can use the formula for average velocity to solve the problem. Solution
2.1
Discussion Since average velocity is a vector quantity, you must include direction as well as magnitude in the answer. Notice, however, that the direction can be omitted until the end to avoid cluttering the problem. Pay attention to the significant figures in the problem. The distance 304 m has three significant figures, but the time interval 180 s has only two, so the quotient should have only two significant figures.
TIPS FOR SUCCESS Note the way scalars and vectors are represented. In this book d represents distance and displacement. Similarly, v represents speed, and v represents velocity. A variable that is not bold indicates a scalar quantity, and a bold variable indicates a vector quantity. Vectors are sometimes represented by small arrows above the variable.
WORKED EXAMPLE
Solving for Displacement when Average Velocity and Time are Known
Layla jogs with an average velocity of 2.4 m/s east. What is her displacement after 46 seconds? Strategy We know that Layla's average velocity is 2.4 m/s east, and the time interval is 46 seconds. We can rearrange the average velocity formula to solve for the displacement. Solution
2.2
Discussion The answer is about 110 m east, which is a reasonable displacement for slightly less than a minute of jogging. A calculator shows the answer as 110.4 m. We chose to write the answer using scientific notation because we wanted to make it clear that we only

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used two significant figures.
TIPS FOR SUCCESS Dimensional analysis is a good way to determine whether you solved a problem correctly. Write the calculation using only units to be sure they match on opposite sides of the equal mark. In the worked example, you have m = (m/s)(s). Since seconds is in the denominator for the average velocity and in the numerator for the time, the unit cancels out leaving only m and, of course, m = m.

WORKED EXAMPLE
Solving for Time when Displacement and Average Velocity are Known
Phillip walks along a straight path from his house to his school. How long will it take him to get to school if he walks 428 m west with an average velocity of 1.7 m/s west? Strategy We know that Phillip's displacement is 428 m west, and his average velocity is 1.7 m/s west. We can calculate the time required for the trip by rearranging the average velocity equation.
Solution
2.3
Discussion Here again we had to use scientific notation because the answer could only have two significant figures. Since time is a scalar, the answer includes only a magnitude and not a direction.
Practice Problems
10. A trucker drives along a straight highway for 0.25 h with a displacement of 16 km south. What is the trucker’s average velocity? a. 4 km/h north b. 4 km/h south c. 64 km/h north d. 64 km/h south
11. A bird flies with an average velocity of 7.5 m/s east from one branch to another in 2.4 s. It then pauses before flying with an average velocity of 6.8 m/s east for 3.5 s to another branch. What is the bird’s total displacement from its starting point? a. 42 m west b. 6 m west c. 6 m east d. 42 m east
Virtual Physics The Walking Man
In this simulation you will put your cursor on the man and move him first in one direction and then in the opposite direction. Keep the Introduction tab active. You can use the Charts tab after you learn about graphing motion later in this chapter. Carefully watch the sign of the numbers in the position and velocity boxes. Ignore the acceleration box for now. See if you can make the man’s position positive while the velocity is negative. Then see if you can do the opposite.

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Click to view content (https://archive.cnx.org/specials/e2ca52af-8c6b-450e-ac2f-9300b38e8739/moving-man/)
GRASP CHECK
Which situation correctly describes when the moving man’s position was negative but his velocity was positive? a. Man moving toward 0 from left of 0 b. Man moving toward 0 from right of 0 c. Man moving away from 0 from left of 0 d. Man moving away from 0 from right of 0

Check Your Understanding
12. Two runners travel along the same straight path. They start at the same time, and they end at the same time, but at the halfway mark, they have different instantaneous velocities. Is it possible for them to have the same average velocity for the trip? a. Yes, because average velocity depends on the net or total displacement. b. Yes, because average velocity depends on the total distance traveled. c. No, because the velocities of both runners must remain the exactly same throughout the journey. d. No, because the instantaneous velocities of the runners must remain same midway but can be different elsewhere.
13. If you divide the total distance traveled on a car trip (as determined by the odometer) by the time for the trip, are you calculating the average speed or the magnitude of the average velocity, and under what circumstances are these two quantities the same? a. Average speed. Both are the same when the car is traveling at a constant speed and changing direction. b. Average speed. Both are the same when the speed is constant and the car does not change its direction. c. Magnitude of average velocity. Both are same when the car is traveling at a constant speed. d. Magnitude of average velocity. Both are same when the car does not change its direction.
14. Is it possible for average velocity to be negative? a. Yes, in cases when the net displacement is negative. b. Yes, if the body keeps changing its direction during motion. c. No, average velocity describes only magnitude and not the direction of motion. d. No, average velocity describes only the magnitude in the positive direction of motion.
2.3 Position vs. Time Graphs
Section Learning Objectives By the end of this section, you will be able to do the following:
• Explain the meaning of slope in position vs. time graphs • Solve problems using position vs. time graphs
Section Key Terms

dependent variable independent variable tangent

Graphing Position as a Function of Time

A graph, like a picture, is worth a thousand words. Graphs not only contain numerical information, they also reveal relationships between physical quantities. In this section, we will investigate kinematics by analyzing graphs of position over time.

Graphs in this text have perpendicular axes, one horizontal and the other vertical. When two physical quantities are plotted

against each other, the horizontal axis is usually considered the independent variable, and the vertical axis is the dependent

variable. In algebra, you would have referred to the horizontal axis as the x-axis and the vertical axis as the y-axis. As in Figure

2.10, a straight-line graph has the general form

.

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Here m is the slope, defined as the rise divided by the run (as seen in the figure) of the straight line. The letter b is the y-intercept which is the point at which the line crosses the vertical, y-axis. In terms of a physical situation in the real world, these quantities will take on a specific significance, as we will see below. (Figure 2.10.)

Figure 2.10 The diagram shows a straight-line graph. The equation for the straight line is y equals mx + b.
In physics, time is usually the independent variable. Other quantities, such as displacement, are said to depend upon it. A graph of position versus time, therefore, would have position on the vertical axis (dependent variable) and time on the horizontal axis (independent variable). In this case, to what would the slope and y-intercept refer? Let’s look back at our original example when studying distance and displacement.
The drive to school was 5 km from home. Let’s assume it took 10 minutes to make the drive and that your parent was driving at a constant velocity the whole time. The position versus time graph for this section of the trip would look like that shown in Figure 2.11.

Figure 2.11 A graph of position versus time for the drive to school is shown. What would the graph look like if we added the return trip?
As we said before, d0 = 0 because we call home our O and start calculating from there. In Figure 2.11, the line starts at d = 0, as well. This is the b in our equation for a straight line. Our initial position in a position versus time graph is always the place where the graph crosses the x-axis at t = 0. What is the slope? The rise is the change in position, (i.e., displacement) and the run is the change in time. This relationship can also be written
2.4
This relationship was how we defined average velocity. Therefore, the slope in a d versus t graph, is the average velocity.
TIPS FOR SUCCESS
Sometimes, as is the case where we graph both the trip to school and the return trip, the behavior of the graph looks different during different time intervals. If the graph looks like a series of straight lines, then you can calculate the average velocity for each time interval by looking at the slope. If you then want to calculate the average velocity for the entire trip, you can do a
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2.3 • Position vs. Time Graphs

69

weighted average.
Let’s look at another example. Figure 2.12 shows a graph of position versus time for a jet-powered car on a very flat dry lake bed in Nevada.

Figure 2.12 The diagram shows a graph of position versus time for a jet-powered car on the Bonneville Salt Flats.
Using the relationship between dependent and independent variables, we see that the slope in the graph in Figure 2.12 is average velocity, vavg and the intercept is displacement at time zero—that is, d0. Substituting these symbols into y = mx + b gives
2.5
or
2.6
Thus a graph of position versus time gives a general relationship among displacement, velocity, and time, as well as giving detailed numerical information about a specific situation. From the figure we can see that the car has a position of 400 m at t = 0 s, 650 m at t = 1.0 s, and so on. And we can learn about the object’s velocity, as well.
Snap Lab
Graphing Motion
In this activity, you will release a ball down a ramp and graph the ball’s displacement vs. time.
• Choose an open location with lots of space to spread out so there is less chance for tripping or falling due to rolling balls.
• 1 ball • 1 board • 2 or 3 books • 1 stopwatch • 1 tape measure • 6 pieces of masking tape • 1 piece of graph paper • 1 pencil
Procedure 1. Build a ramp by placing one end of the board on top of the stack of books. Adjust location, as necessary, until there is
no obstacle along the straight line path from the bottom of the ramp until at least the next 3 m. 2. Mark distances of 0.5 m, 1.0 m, 1.5 m, 2.0 m, 2.5 m, and 3.0 m from the bottom of the ramp. Write the distances on the
tape.

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3. Have one person take the role of the experimenter. This person will release the ball from the top of the ramp. If the ball does not reach the 3.0 m mark, then increase the incline of the ramp by adding another book. Repeat this Step as necessary.
4. Have the experimenter release the ball. Have a second person, the timer, begin timing the trial once the ball reaches the bottom of the ramp and stop the timing once the ball reaches 0.5 m. Have a third person, the recorder, record the time in a data table.
5. Repeat Step 4, stopping the times at the distances of 1.0 m, 1.5 m, 2.0 m, 2.5 m, and 3.0 m from the bottom of the ramp.
6. Use your measurements of time and the displacement to make a position vs. time graph of the ball’s motion. 7. Repeat Steps 4 through 6, with different people taking on the roles of experimenter, timer, and recorder. Do you get the
same measurement values regardless of who releases the ball, measures the time, or records the result? Discuss possible causes of discrepancies, if any.
GRASP CHECK
True or False: The average speed of the ball will be less than the average velocity of the ball. a. True b. False

Solving Problems Using Position vs. Time Graphs
So how do we use graphs to solve for things we want to know like velocity?
WORKED EXAMPLE
Using Position–Time Graph to Calculate Average Velocity: Jet Car
Find the average velocity of the car whose position is graphed in Figure 1.13. Strategy The slope of a graph of d vs. t is average velocity, since slope equals rise over run.
2.7
Since the slope is constant here, any two points on the graph can be used to find the slope. Solution 1. Choose two points on the line. In this case, we choose the points labeled on the graph: (6.4 s, 2000 m) and (0.50 s, 525 m).
(Note, however, that you could choose any two points.) 2. Substitute the d and t values of the chosen points into the equation. Remember in calculating change (Δ) we always use
final value minus initial value.
2.8
Discussion This is an impressively high land speed (900 km/h, or about 560 mi/h): much greater than the typical highway speed limit of 27 m/s or 96 km/h, but considerably shy of the record of 343 m/s or 1,234 km/h, set in 1997.
But what if the graph of the position is more complicated than a straight line? What if the object speeds up or turns around and goes backward? Can we figure out anything about its velocity from a graph of that kind of motion? Let’s take another look at the jet-powered car. The graph in Figure 2.13 shows its motion as it is getting up to speed after starting at rest. Time starts at zero for this motion (as if measured with a stopwatch), and the displacement and velocity are initially 200 m and 15 m/s, respectively.

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71

Figure 2.13 The diagram shows a graph of the position of a jet-powered car during the time span when it is speeding up. The slope of a distance versus time graph is velocity. This is shown at two points. Instantaneous velocity at any point is the slope of the tangent at that point.

Figure 2.14 A U.S. Air Force jet car speeds down a track. (Matt Trostle, Flickr)
The graph of position versus time in Figure 2.13 is a curve rather than a straight line. The slope of the curve becomes steeper as time progresses, showing that the velocity is increasing over time. The slope at any point on a position-versus-time graph is the instantaneous velocity at that point. It is found by drawing a straight line tangent to the curve at the point of interest and taking the slope of this straight line. Tangent lines are shown for two points in Figure 2.13. The average velocity is the net displacement divided by the time traveled.

WORKED EXAMPLE

Using Position–Time Graph to Calculate Average Velocity: Jet Car, Take Two
Calculate the instantaneous velocity of the jet car at a time of 25 s by finding the slope of the tangent line at point Q in Figure 2.13. Strategy The slope of a curve at a point is equal to the slope of a straight line tangent to the curve at that point.

Solution

1. Find the tangent line to the curve at

.

2. Determine the endpoints of the tangent. These correspond to a position of 1,300 m at time 19 s and a position of 3120 m at

time 32 s.

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3. Plug these endpoints into the equation to solve for the slope, v.

2.9

Discussion The entire graph of v versus t can be obtained in this fashion.
Practice Problems
15. Calculate the average velocity of the object shown in the graph below over the whole time interval.

a. 0.25 m/s b. 0.31 m/s c. 3.2 m/s d. 4.00 m/s

16. True or False: By taking the slope of the curve in the graph you can verify that the velocity of the jet car is

at

.

a. True b. False
Check Your Understanding
17. Which of the following information about motion can be determined by looking at a position vs. time graph that is a straight line?
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a. frame of reference b. average acceleration c. velocity d. direction of force applied
18. True or False: The position vs time graph of an object that is speeding up is a straight line. a. True b. False
2.4 Velocity vs. Time Graphs
Section Learning Objectives By the end of this section, you will be able to do the following:
• Explain the meaning of slope and area in velocity vs. time graphs • Solve problems using velocity vs. time graphs
Section Key Terms
acceleration
Graphing Velocity as a Function of Time
Earlier, we examined graphs of position versus time. Now, we are going to build on that information as we look at graphs of velocity vs. time. Velocity is the rate of change of displacement. Acceleration is the rate of change of velocity; we will discuss acceleration more in another chapter. These concepts are all very interrelated.
Virtual Physics
Maze Game
In this simulation you will use a vector diagram to manipulate a ball into a certain location without hitting a wall. You can manipulate the ball directly with position or by changing its velocity. Explore how these factors change the motion. If you would like, you can put it on the a setting, as well. This is acceleration, which measures the rate of change of velocity. We will explore acceleration in more detail later, but it might be interesting to take a look at it here.
Click to view content (https://archive.cnx.org/specials/30e37034-2fbd-11e5-83a2-03be60006ece/maze-game/)
GRASP CHECK
Click to view content (https://archive.cnx.org/specials/30e37034-2fbd-11e5-83a2-03be60006ece/maze-game/#sim-mazegame) a. The ball can be easily manipulated with displacement because the arena is a position space. b. The ball can be easily manipulated with velocity because the arena is a position space. c. The ball can be easily manipulated with displacement because the arena is a velocity space. d. The ball can be easily manipulated with velocity because the arena is a velocity space.

What can we learn about motion by looking at velocity vs. time graphs? Let’s return to our drive to school, and look at a graph of position versus time as shown in Figure 2.15.

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Figure 2.15 A graph of position versus time for the drive to and from school is shown.
We assumed for our original calculation that your parent drove with a constant velocity to and from school. We now know that the car could not have gone from rest to a constant velocity without speeding up. So the actual graph would be curved on either end, but let’s make the same approximation as we did then, anyway.
TIPS FOR SUCCESS
It is common in physics, especially at the early learning stages, for certain things to be neglected, as we see here. This is because it makes the concept clearer or the calculation easier. Practicing physicists use these kinds of short-cuts, as well. It works out because usually the thing being neglected is small enough that it does not significantly affect the answer. In the earlier example, the amount of time it takes the car to speed up and reach its cruising velocity is very small compared to the total time traveled. Looking at this graph, and given what we learned, we can see that there are two distinct periods to the car’s motion—the way to school and the way back. The average velocity for the drive to school is 0.5 km/minute. We can see that the average velocity for the drive back is –0.5 km/minute. If we plot the data showing velocity versus time, we get another graph (Figure 2.16):
Figure 2.16 Graph of velocity versus time for the drive to and from school.
We can learn a few things. First, we can derive a v versus t graph from a d versus t graph. Second, if we have a straight-line position–time graph that is positively or negatively sloped, it will yield a horizontal velocity graph. There are a few other interesting things to note. Just as we could use a position vs. time graph to determine velocity, we can use a velocity vs. time graph to determine position. We know that v = d/t. If we use a little algebra to re-arrange the equation, we see that d = v t. In Figure 2.16, we have velocity on the y-axis and time along the x-axis. Let’s take just the first half of the motion. We get 0.5 km/ minute 10 minutes. The units for minutes cancel each other, and we get 5 km, which is the displacement for the trip to school. If we calculate the same for the return trip, we get –5 km. If we add them together, we see that the net displacement for the
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2.4 • Velocity vs. Time Graphs

75

whole trip is 0 km, which it should be because we started and ended at the same place.
TIPS FOR SUCCESS
You can treat units just like you treat numbers, so a km/km=1 (or, we say, it cancels out). This is good because it can tell us whether or not we have calculated everything with the correct units. For instance, if we end up with m × s for velocity instead of m/s, we know that something has gone wrong, and we need to check our math. This process is called dimensional analysis, and it is one of the best ways to check if your math makes sense in physics.
The area under a velocity curve represents the displacement. The velocity curve also tells us whether the car is speeding up. In our earlier example, we stated that the velocity was constant. So, the car is not speeding up. Graphically, you can see that the slope of these two lines is 0. This slope tells us that the car is not speeding up, or accelerating. We will do more with this information in a later chapter. For now, just remember that the area under the graph and the slope are the two important parts of the graph. Just like we could define a linear equation for the motion in a position vs. time graph, we can also define one for a velocity vs. time graph. As we said, the slope equals the acceleration, a. And in this graph, the y-intercept is v0. Thus,
.
But what if the velocity is not constant? Let’s look back at our jet-car example. At the beginning of the motion, as the car is speeding up, we saw that its position is a curve, as shown in Figure 2.17.

Figure 2.17 A graph is shown of the position of a jet-powered car during the time span when it is speeding up. The slope of a d vs. t graph is velocity. This is shown at two points. Instantaneous velocity at any point is the slope of the tangent at that point.
You do not have to do this, but you could, theoretically, take the instantaneous velocity at each point on this graph. If you did, you would get Figure 2.18, which is just a straight line with a positive slope.

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Chapter 2 • Motion in One Dimension

Figure 2.18 The graph shows the velocity of a jet-powered car during the time span when it is speeding up.
Again, if we take the slope of the velocity vs. time graph, we get the acceleration, the rate of change of the velocity. And, if we take the area under the slope, we get back to the displacement.
Solving Problems using Velocity–Time Graphs
Most velocity vs. time graphs will be straight lines. When this is the case, our calculations are fairly simple.
WORKED EXAMPLE
Using Velocity Graph to Calculate Some Stuff: Jet Car
Use this figure to (a) find the displacement of the jet car over the time shown (b) calculate the rate of change (acceleration) of the velocity. (c) give the instantaneous velocity at 5 s, and (d) calculate the average velocity over the interval shown. Strategy a. The displacement is given by finding the area under the line in the velocity vs. time graph. b. The acceleration is given by finding the slope of the velocity graph. c. The instantaneous velocity can just be read off of the graph. d. To find the average velocity, recall that
Solution a. 1. Analyze the shape of the area to be calculated. In this case, the area is made up of a rectangle between 0 and 20 m/s
stretching to 30 s. The area of a rectangle is length width. Therefore, the area of this piece is 600 m. 2. Above that is a triangle whose base is 30 s and height is 140 m/s. The area of a triangle is 0.5 length width. The area
of this piece, therefore, is 2,100 m. 3. Add them together to get a net displacement of 2,700 m. b. 1. Take two points on the velocity line. Say, t = 5 s and t = 25 s. At t = 5 s, the value of v = 40 m/s.
At t = 25 s, v = 140 m/s.
2. Find the slope.
c. The instantaneous velocity at t = 5 s, as we found in part (b) is just 40 m/s. d. 1. Find the net displacement, which we found in part (a) was 2,700 m.
2. Find the total time which for this case is 30 s. 3. Divide 2,700 m/30 s = 90 m/s.
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2.4 • Velocity vs. Time Graphs

77

Discussion The average velocity we calculated here makes sense if we look at the graph. 100m/s falls about halfway across the graph and since it is a straight line, we would expect about half the velocity to be above and half below.

TIPS FOR SUCCESS
You can have negative position, velocity, and acceleration on a graph that describes the way the object is moving. You should never see a graph with negative time on an axis. Why?
Most of the velocity vs. time graphs we will look at will be simple to interpret. Occasionally, we will look at curved graphs of velocity vs. time. More often, these curved graphs occur when something is speeding up, often from rest. Let’s look back at a more realistic velocity vs. time graph of the jet car’s motion that takes this speeding up stage into account.

Figure 2.19 The graph shows a more accurate graph of the velocity of a jet-powered car during the time span when it is speeding up.
WORKED EXAMPLE
Using Curvy Velocity Graph to Calculate Some Stuff: jet car, Take Two
Use Figure 2.19 to (a) find the approximate displacement of the jet car over the time shown, (b) calculate the instantaneous acceleration at t = 30 s, (c) find the instantaneous velocity at 30 s, and (d) calculate the approximate average velocity over the interval shown. Strategy a. Because this graph is an undefined curve, we have to estimate shapes over smaller intervals in order to find the areas. b. Like when we were working with a curved displacement graph, we will need to take a tangent line at the instant we are
interested and use that to calculate the instantaneous acceleration. c. The instantaneous velocity can still be read off of the graph. d. We will find the average velocity the same way we did in the previous example.
Solution a. 1. This problem is more complicated than the last example. To get a good estimate, we should probably break the curve
into four sections. 0 → 10 s, 10 → 20 s, 20 → 40 s, and 40 → 70 s. 2. Calculate the bottom rectangle (common to all pieces). 165 m/s 70 s = 11,550 m. 3. Estimate a triangle at the top, and calculate the area for each section. Section 1 = 225 m; section 2 = 100 m + 450 m =
550 m; section 3 = 150 m + 1,300 m = 1,450 m; section 4 = 2,550 m. 4. Add them together to get a net displacement of 16,325 m.
b. Using the tangent line given, we find that the slope is 1 m/s2.

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Chapter 2 • Motion in One Dimension

c. The instantaneous velocity at t = 30 s, is 240 m/s. d. 1. Find the net displacement, which we found in part (a), was 16,325 m.
2. Find the total time, which for this case is 70 s. 3. Divide
Discussion This is a much more complicated process than the first problem. If we were to use these estimates to come up with the average velocity over just the first 30 s we would get about 191 m/s. By approximating that curve with a line, we get an average velocity of 202.5 m/s. Depending on our purposes and how precise an answer we need, sometimes calling a curve a straight line is a worthwhile approximation.
Practice Problems
19.

Figure 2.20
Consider the velocity vs. time graph shown below of a person in an elevator. Suppose the elevator is initially at rest. It then speeds up for 3 seconds, maintains that velocity for 15 seconds, then slows down for 5 seconds until it stops. Find the instantaneous velocity at t = 10 s and t = 23 s. a. Instantaneous velocity at t = 10 s and t = 23 s are 0 m/s and 0 m/s. b. Instantaneous velocity at t = 10 s and t = 23 s are 0 m/s and 3 m/s. c. Instantaneous velocity at t = 10 s and t = 23 s are 3 m/s and 0 m/s. d. Instantaneous velocity at t = 10 s and t = 23 s are 3 m/s and 1.5 m/s.

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2.4 • Velocity vs. Time Graphs

79

20.

Figure 2.21
Calculate the net displacement and the average velocity of the elevator over the time interval shown. a. Net displacement is 45 m and average velocity is 2.10 m/s. b. Net displacement is 45 m and average velocity is 2.28 m/s. c. Net displacement is 57 m and average velocity is 2.66 m/s. d. Net displacement is 57 m and average velocity is 2.48 m/s.
Snap Lab
Graphing Motion, Take Two
In this activity, you will graph a moving ball’s velocity vs. time.
• your graph from the earlier Graphing Motion Snap Lab! • 1 piece of graph paper • 1 pencil
Procedure 1. Take your graph from the earlier Graphing Motion Snap Lab! and use it to create a graph of velocity vs. time. 2. Use your graph to calculate the displacement.
GRASP CHECK
Describe the graph and explain what it means in terms of velocity and acceleration. a. The graph shows a horizontal line indicating that the ball moved with a constant velocity, that is, it was not
accelerating. b. The graph shows a horizontal line indicating that the ball moved with a constant velocity, that is, it was
accelerating. c. The graph shows a horizontal line indicating that the ball moved with a variable velocity, that is, it was not
accelerating. d. The graph shows a horizontal line indicating that the ball moved with a variable velocity, that is, it was accelerating.
Check Your Understanding
21. What information could you obtain by looking at a velocity vs. time graph? a. acceleration b. direction of motion c. reference frame of the motion

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Chapter 2 • Motion in One Dimension

d. shortest path
22. How would you use a position vs. time graph to construct a velocity vs. time graph and vice versa? a. Slope of position vs. time curve is used to construct velocity vs. time curve, and slope of velocity vs. time curve is used to construct position vs. time curve. b. Slope of position vs. time curve is used to construct velocity vs. time curve, and area of velocity vs. time curve is used to construct position vs. time curve. c. Area of position vs. time curve is used to construct velocity vs. time curve, and slope of velocity vs. time curve is used to construct position vs. time curve. d. Area of position/time curve is used to construct velocity vs. time curve, and area of velocity vs. time curve is used to construct position vs. time curve.

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Chapter 2 • Key Terms 81

KEY TERMS
acceleration the rate at which velocity changes average speed distance traveled divided by time during
which motion occurs average velocity displacement divided by time over which
displacement occurs dependent variable the variable that changes as the
independent variable changes displacement the change in position of an object against a
fixed axis distance the length of the path actually traveled between an
initial and a final position independent variable the variable, usually along the
horizontal axis of a graph, that does not change based on human or experimental action; in physics this is usually
SECTION SUMMARY
2.1 Relative Motion, Distance, and Displacement
• A description of motion depends on the reference frame from which it is described.
• The distance an object moves is the length of the path along which it moves.
• Displacement is the difference in the initial and final positions of an object.
2.2 Speed and Velocity
• Average speed is a scalar quantity that describes distance traveled divided by the time during which the motion occurs.
• Velocity is a vector quantity that describes the speed and direction of an object.
• Average velocity is displacement over the time period during which the displacement occurs. If the velocity is constant, then average velocity and instantaneous
KEY EQUATIONS
2.1 Relative Motion, Distance, and Displacement
Displacement
2.2 Speed and Velocity
Average speed
Average velocity

time instantaneous speed speed at a specific instant in time instantaneous velocity velocity at a specific instant in time kinematics the study of motion without considering its
causes magnitude size or amount position the location of an object at any particular time reference frame a coordinate system from which the
positions of objects are described scalar a quantity that has magnitude but no direction speed rate at which an object changes its location tangent a line that touches another at exactly one point vector a quantity that has both magnitude and direction velocity the speed and direction of an object
velocity are the same.
2.3 Position vs. Time Graphs
• Graphs can be used to analyze motion. • The slope of a position vs. time graph is the velocity. • For a straight line graph of position, the slope is the
average velocity. • To obtain the instantaneous velocity at a given moment
for a curved graph, find the tangent line at that point and take its slope.
2.4 Velocity vs. Time Graphs
• The slope of a velocity vs. time graph is the acceleration. • The area under a velocity vs. time curve is the
displacement. • Average velocity can be found in a velocity vs. time
graph by taking the weighted average of all the velocities.

2.3 Position vs. Time Graphs

Displacement

.

2.4 Velocity vs. Time Graphs
Velocity Acceleration

82 Chapter 2 • Chapter Review

CHAPTER REVIEW
Concept Items
2.1 Relative Motion, Distance, and Displacement
1. Can one-dimensional motion have zero distance but a nonzero displacement? What about zero displacement but a nonzero distance? a. One-dimensional motion can have zero distance with a nonzero displacement. Displacement has both magnitude and direction, and it can also have zero displacement with nonzero distance because distance has only magnitude. b. One-dimensional motion can have zero distance with a nonzero displacement. Displacement has both magnitude and direction, but it cannot have zero displacement with nonzero distance because distance has only magnitude. c. One-dimensional motion cannot have zero distance with a nonzero displacement. Displacement has both magnitude and direction, but it can have zero displacement with nonzero distance because distance has only magnitude and any motion will be the distance it moves. d. One-dimensional motion cannot have zero distance with a nonzero displacement. Displacement has both magnitude and direction, and it cannot have zero displacement with nonzero distance because distance has only magnitude.
2. In which example would you be correct in describing an object in motion while your friend would also be correct in describing that same object as being at rest? a. You are driving a car toward the east and your friend drives past you in the opposite direction with the same speed. In your frame of reference, you will be in motion. In your friend’s frame of reference, you will be at rest. b. You are driving a car toward the east and your friend is standing at the bus stop. In your frame of reference, you will be in motion. In your friend’s frame of reference, you will be at rest. c. You are driving a car toward the east and your friend is standing at the bus stop. In your frame of reference, your friend will be moving toward the west. In your friend’s frame of reference, he will be at rest. d. You are driving a car toward the east and your friend is standing at the bus stop. In your frame of reference, your friend will be moving toward the east. In your friend’s frame of reference, he will be at rest.

3. What does your car’s odometer record? a. displacement b. distance c. both distance and displacement d. the sum of distance and displacement
2.2 Speed and Velocity
4. In the definition of velocity, what physical quantity is changing over time? a. speed b. distance c. magnitude of displacement d. position vector
5. Which of the following best describes the relationship between instantaneous velocity and instantaneous speed? a. Both instantaneous speed and instantaneous velocity are the same, even when there is a change in direction. b. Instantaneous speed and instantaneous velocity cannot be the same even if there is no change in direction of motion. c. Magnitude of instantaneous velocity is equal to instantaneous speed. d. Magnitude of instantaneous velocity is always greater than instantaneous speed.
2.3 Position vs. Time Graphs
6. Use the graph to describe what the runner’s motion looks like.
How are average velocity for only the first four seconds and instantaneous velocity related? What is the runner's net displacement over the time shown? a. The net displacement is 12 m and the average velocity
is equal to the instantaneous velocity. b. The net displacement is 12 m and the average velocity

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Chapter 2 • Chapter Review 83

is two times the instantaneous velocity. c. The net displacement is 10 + 12 = 22 m and the average
velocity is equal to the instantaneous velocity. d. The net displacement is 10 + 12 = 22 m and the average
velocity is two times the instantaneous velocity.

7. A position vs. time graph of a frog swimming across a

pond has two distinct straight-line sections. The slope of

the first section is

. The slope of the second section

is

. If each section lasts

, then what is the

frog’s total average velocity?

a.

b.

c.

d.

2.4 Velocity vs. Time Graphs
8. A graph of velocity vs. time of a ship coming into a harbor is shown.

Describe the acceleration of the ship based on the graph. a. The ship is moving in the forward direction at a steady
rate. Then it accelerates in the forward direction and then decelerates. b. The ship is moving in the forward direction at a steady rate. Then it turns around and starts decelerating, while traveling in the reverse direction. It then accelerates, but slowly. c. The ship is moving in the forward direction at a steady rate. Then it decelerates in the forward direction, and then continues to slow down in the forward direction, but with more deceleration. d. The ship is moving in the forward direction at a steady rate. Then it decelerates in the forward direction, and then continues to slow down in the forward direction, but with less deceleration.

Critical Thinking Items
2.1 Relative Motion, Distance, and Displacement
9. Boat A and Boat B are traveling at a constant speed in opposite directions when they pass each other. If a person in each boat describes motion based on the boat’s own reference frame, will the description by a person in Boat A of Boat B’s motion be the same as the description by a person in Boat B of Boat A’s motion? a. Yes, both persons will describe the same motion because motion is independent of the frame of reference. b. Yes, both persons will describe the same motion because they will perceive the other as moving in the backward direction. c. No, the motion described by each of them will be different because motion is a relative term. d. No, the motion described by each of them will be different because the motion perceived by each will be opposite to each other.
10. Passenger A sits inside a moving train and throws a ball vertically upward. How would the motion of the ball be described by a fellow train passenger B and an observer

C who is standing on the platform outside the train? a. Passenger B sees that the ball has vertical, but no
horizontal, motion. Observer C sees the ball has vertical as well as horizontal motion. b. Passenger B sees the ball has vertical as well as horizontal motion. Observer C sees the ball has the vertical, but no horizontal, motion. c. Passenger B sees the ball has horizontal but no vertical motion. Observer C sees the ball has vertical as well as horizontal motion. d. Passenger B sees the ball has vertical as well as horizontal motion. Observer C sees the ball has horizontalbut no vertical motion.
2.2 Speed and Velocity
11. Is it possible to determine a car’s instantaneous velocity from just the speedometer reading? a. No, it reflects speed but not the direction. b. No, it reflects the average speed of the car. c. Yes, it sometimes reflects instantaneous velocity of the car. d. Yes, it always reflects the instantaneous velocity of the car.
12. Terri, Aaron, and Jamal all walked along straight paths.

84 Chapter 2 • Chapter Review

Terri walked 3.95 km north in 48 min. Aaron walked 2.65 km west in 31 min. Jamal walked 6.50 km south in 81 min. Which of the following correctly ranks the three boys in order from lowest to highest average speed? a. Jamal, Terri, Aaron b. Jamal, Aaron, Terri c. Terri, Jamal, Aaron d. Aaron, Terri, Jamal

13. Rhianna and Logan start at the same point and walk due

north. Rhianna walks with an average velocity

.

Logan walks three times the distance in twice the time as

Rhianna. Which of the following expresses Logan’s

average velocity in terms of

?

a. Logan’s average velocity =

.

b. Logan’s average velocity =

.

c. Logan’s average velocity =

.

d. Logan’s average velocity =

.

2.3 Position vs. Time Graphs
14. Explain how you can use the graph of position vs. time to describe the change in velocity over time.

Identify the time (ta, tb, tc, td, or te) at which at which the instantaneous velocity is greatest, the time at which it is zero, and the time at which it is negative.
2.4 Velocity vs. Time Graphs
15. Identify the time, or times, at which the instantaneous velocity is greatest, and the time, or times, at which it is negative. A sketch of velocity vs. time derived from the figure will aid in arriving at the correct answers.
a. The instantaneous velocity is greatest at f, and it is negative at d, h, I, j, and k.
b. The instantaneous velocity is greatest at e, and it is negative at a, b, and f.
c. The instantaneous velocity is greatest at f, and it is negative at d, h, I, j, and k
d. The instantaneous velocity is greatest at d, and it is negative at a, b, and f.

Problems

2.1 Relative Motion, Distance, and Displacement

16. In a coordinate system in which the direction to the

right is positive, what are the distance and displacement

of a person who walks

to the left,

to the right, and then

to the left?

a. Distance is

and displacement is

.

b. Distance is

and displacement is .

c. Distance is

and displacement is

.

d. Distance is

and displacement is .

17. Billy drops a ball from a height of 1 m. The ball bounces back to a height of 0.8 m, then bounces again to a height of 0.5 m, and bounces once more to a height of 0.2 m.

Up is the positive direction. What are the total displacement of the ball and the total distance traveled by the ball? a. The displacement is equal to -4 m and the distance
is equal to 4 m. b. The displacement is equal to 4 m and the distance is
equal to 1 m. c. The displacement is equal to 4 m and the distance is
equal to 1 m. d. The displacement is equal to -1 m and the distance
is equal to 4 m.
2.2 Speed and Velocity
18. You sit in a car that is moving at an average speed of 86.4 km/h. During the 3.3 s that you glance out the window, how far has the car traveled?

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Chapter 2 • Chapter Review 85

a. 7.27 m b. 79 m c. 285 km d. 1026 m
2.3 Position vs. Time Graphs
19. Using the graph, what is the average velocity for the whole 10 seconds?

moments in time. What is the minimum number of data points you would need to estimate the average acceleration of the object? a. 1 b. 2 c. 3 d. 4
22. Which option best describes the average acceleration from 40 to 70 s?

a. The total average velocity is 0 m/s. b. The total average velocity is 1.2 m/s. c. The total average velocity is 1.5 m/s. d. The total average velocity is 3.0 m/s.
20. A train starts from rest and speeds up for 15 minutes until it reaches a constant velocity of 100 miles/hour. It stays at this speed for half an hour. Then it slows down for another 15 minutes until it is still. Which of the following correctly describes the position vs time graph of the train’s journey? a. The first 15 minutes is a curve that is concave upward, the middle portion is a straight line with slope 100 miles/hour, and the last portion is a concave downward curve. b. The first 15 minutes is a curve that is concave downward, the middle portion is a straight line with slope 100 miles/hour, and the last portion is a concave upward curve. c. The first 15 minutes is a curve that is concave upward, the middle portion is a straight line with slope zero, and the last portion is a concave downward curve. d. The first 15 minutes is a curve that is concave downward, the middle portion is a straight line with slope zero, and the last portion is a concave upward curve.
2.4 Velocity vs. Time Graphs
21. You are characterizing the motion of an object by measuring the location of the object at discrete

a. It is negative and smaller in magnitude than the initial acceleration.
b. It is negative and larger in magnitude than the initial acceleration.
c. It is positive and smaller in magnitude than the initial acceleration.
d. It is positive and larger in magnitude than the initial acceleration.
23. The graph shows velocity vs. time.
Calculate the net displacement using seven different divisions. Calculate it again using two divisions: 0 → 40 s

86 Chapter 2 • Test Prep
and 40 → 70 s . Compare. Using both, calculate the average velocity. a. Displacement and average velocity using seven
divisions are 14,312.5 m and 204.5 m/s while with two divisions are 15,500 m and 221.4 m/s respectively. b. Displacement and average velocity using seven divisions are 15,500 m and 221.4 m/s while with two
Performance Task
2.4 Velocity vs. Time Graphs
24. The National Mall in Washington, DC, is a national park containing most of the highly treasured memorials and museums of the United States. However, the National Mall also hosts many events and concerts. The map in shows the area for a benefit concert during which the president will speak. The concert stage is near the Lincoln Memorial. The seats and standing room for the crowd will stretch from the stage east to near the Washington Monument, as shown on the map. You are planning the logistics for the concert. Use the map scale to measure any distances needed to make the calculations below.

divisions are 14,312.5 m and 204.5 m/s respectively. c. Displacement and average velocity using seven
divisions are 15,500 m and 204.5 m/s while with two divisions are 14,312.5 m and 221.4 m/s respectively. d. Displacement and average velocity using seven divisions are 14,312.5 m and 221.4 m/s while with two divisions are 15,500 m and 204.5 m/s respectively.
The park has three new long-distance speakers. They would like to use these speakers to broadcast the concert audio to other parts of the National Mall. The speakers can project sound up to 0.35 miles away but they must be connected to one of the power supplies within the concert area. What is the minimum amount of wire needed for each speaker, in miles, in order to project the audio to the following areas? Assume that wire cannot be placed over buildings or any memorials. Part A. The center of the Jefferson Memorial using power supply 1 (This will involve an elevated wire that can travel over water.) Part B. The center of the Ellipse using power supply 3 (This wire cannot travel over water.) Part C. The president’s motorcade will be traveling to the concert from the White House. To avoid concert traffic, the motorcade travels from the White House west down E Street and then turns south on 23rd Street to reach the Lincoln memorial. What minimum speed, in miles per hour to the nearest tenth, would the motorcade have to travel to make the trip in 5 minutes? Part D. The president could also simply fly from the White House to the Lincoln Memorial using the presidential helicopter, Marine 1. How long would it take Marine 1, traveling slowly at 30 mph, to travel from directly above the White House landing zone (LZ) to directly above the Lincoln Memorial LZ? Disregard liftoff and landing times and report the travel time in minutes to the nearest minute.

TEST PREP
Multiple Choice
2.1 Relative Motion, Distance, and Displacement
25. Why should you specify a reference frame when describing motion? a. a description of motion depends on the reference frame

b. motion appears the same in all reference frames c. reference frames affect the motion of an object d. you can see motion better from certain reference
frames
26. Which of the following is true for the displacement of an object? a. It is always equal to the distance the object moved

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