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arXiv:1902.03895v1 [gr-qc] 11 Feb 2019
On the general relativistic framework of the Sagnac effect
February 12, 2019
1Elmo Benedetto, 2Fabiano Feleppa, 3Ignazio Licata, 4Hooman Moradpour and 5Christian Corda
1Università di Salerno, Dipartimento di Informatica, Via Giovanni Paolo II, 132, 84084 Fisciano SA
2Department of Physics, University of Trieste, via Valerio 2, 34127 Trieste, Italy
3,4,5Research Institute for Astronomy and Astrophysics of Maragha (RIAAM), P.O. Box 55134-441, Maragha, Iran and International Institute for Applicable Mathematics & Information Sciences (IIAMIS), B.M. Birla Science Centre, Adarsh Nagar, Hyderabad - 500 463, India
E-mails:1
Abstract The Sagnac effect is usually considered as being a relativistic effect produced in an interferometer when the device is rotating. General relativistic explanations are known and already widely explained in many papers. Such general relativistic approaches are founded on Einsteins equivalence principle (EEP), which states the equivalence between the gravitational "force" and the pseudo-force experienced by an observer in a non-inertial frame of reference, included a rotating observer. Typically, the authors consider the so-called Langevin-Landau-Lifschitz metric and the path of light is determined by null geodesics. This approach partially hides the physical meaning of the effect. It seems indeed that the light speed varies by c ± ωr in one or the other direction around the disk. In this paper, a slightly different general relativistic approach will be used. 1elmobenedetto@libero.it; f eleppa.f abiano@gmail.com; ignazio.licata3@gmail.com; hn.moradpour@gmail.com; cordac.galilei@gmail.com.
1
The different "gravitational field" acting on the beam splitter and on the two rays of light is analyzed. This different approach permits a better understanding of the physical meaning of the Sagnac effect.
1 Introduction
It can be useful to recall the context of the discovery of the Sagnac Effect. At the beginning of previous century, physicists were engaged in a very long debate concerning absolute space and its counterpart, the aether, the hypothetical medium of propagation of light. In the well known gedankenexperiment of the rotating bucket filled with water, Newton deduced the existence of an absolute rotation with respect to absolute space. In one of the most important work in the history of science (Principia), he expatiated on time, absolute and relative space and motion [1]. Mach criticized Newtons reasoning in his book published in 1893 [2]. From his perspective, one must consider the rotation of water relative to all the matter in the Universe. It is well known that Machs ideas had a considerable influence on the development of Albert Einsteins general theory of relativity (GTR), especially during the first years of the 20th century. Machs view led to a misconception about the GTR. A more complete analysis of the debate can be find in [3]. After the formulation of the special theory of relativity and before its generalization to the GTR, also the French physicist Georges Sagnac took part in the debate. In 1899, he indeed developed a theory of the existence of a motionless mechanical aether [4]. His aim was to explain all optics phenomena within this theoretical framework, with special attention to the Fresnel-Fizeau experiment for the drag of light in a moving medium [5, 6]. At the beginning of the 20th century, he conceived a rotating interferometer to test his ideas. Despite countless explanations, in more than a hundred years, there are still different interpretations of Sagnac experiment in the framework of the GTR. But this is not a rare thing in physics. In fact, it is not the only topic that, although it is well known in the scientific literature, still requires insights and explanations [7, 8]. In order to start, in next Sections, the Sagnac effect in the framework of Classical Mechanics will be briefly analyzed.
2 The Sagnac experiment within the framework of Classical Mechanics
One considers two light rays in opposite directions around a static circular loop of radius r. Such light rays will arrive at the end point simultaneously. Instead, if the loop is rotating, the ray travelling in the same direction as the rotation of the loop must travel a distance greater than the ray travelling in the opposite direction. For this reason, the counter-rotating ray will arrive earlier than the co-rotating ray. The length of the path is L = 2πr and, if there is not angular velocity of the loop, the duration of the path is
2
∆t = 2πr .
(1)
c
Instead, in the presence of an angular velocity ω = 0, one writes
c∆t1 = 2πr + rω∆t1,
(2)
c∆t2 = 2πr rω∆t2,
(3)
from which one obtains
∆t1
=
2πr , c
(4)
∆t2
=
2πr c + rω .
(5)
Assuming ω2r2 ≪ c2, the difference in the journey times is
∆t
=
∆t1
∆t2
=
4πr2ω c2 ω2r2
4πr2ω .
c2
(6)
3 The Sagnac effect within the framework of the GTR
The scientific literature on the relativistic Sagnac effect is very wide, see [8 24] for details. In this paragraph, its standard derivation in the framework of the GTR will be considered. Let us recall the standard flat Lorentz-Minkowski metric in cylindrical coordinates
ds2 = c2dt2 dr2 r2dθ2 dz2.
(7)
If one considers a system rotating at angular velocity ω, one gets the angle transform as θ = θ′ + ωt. Thus, dθ = dθ + ωdt. Starting from these considerations, the metric becomes the so called Langevin-Landau-Lifschitz metric [25, 26]
ds2 = (c2 ω2r2)dt2 dr2 r2dθ2 dz2 2r2ωdθdt.
(8)
Inserting the condition of null geodesics ds = 0 in Eq. (8), one gets
1
ω2r2 c2
c2dt2 dr2 r2dθ2 dz2 2r2ωdθdt = 0.
(9)
Equation (8) describes a stationary metric which is a solution of Einstein field equations in empty space. The EEP permits to interpret it in terms of a gravitational field [25]. Besides, knowing how tensors behave, one has
Rijkl(t, x, y, z) = 0 ⇒ Rijkl(t, r, θ′, z) = 0,
(10)
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where Rijkl is the Riemann curvature tensor. Following [27], the spatial metric can be written as
dl2 =
gαβ
+
g0αg0β g00
dxα dxβ .
(11)
Hence, a bit of algebra gives
dl2 =
dr2
+
dz2
+
r2dθ2
1
ω2r2 c2
.
(12)
Considering plane motion, one sets dz = 0 and, finally, one obtains
dl =
rdθ .
1
ω2r2 c2
(13)
Thus, by integrating Eq. (13), the length of the circumference is easily written down as
ˆ l=
0
rdθ =
1
ω2r2 c2
2πr .
1
ω2r2 c2
(14)
Within the platform, the observer on the beam splitter expects both rays to
arrive
in
a
time
t
=
l c
.
At
this
point,
generally
one
studies
the
spacetime
metric
ds2 = c2 dt2 2r2dθωdt r2dθ2,
(15)
and the path of the light rays is determined through the condition of null geodesics ds2 = 0. This condition gives
dt
=
r2ωdθ
√ ± r4ω2dθ2
c2
+ c2r2dθ2
=
r2ωdθ ± r2dθ c2
ω2
+
c2 r2
,
(16)
which is well approximated by
dt
r2ωdθ ω c2
±
c r
.
(17)
Then, one gets the solutions
dt1
=
r2ω+cr c2
dt2
=
r2
ωcr c2
.
(18)
By integrating on the periphery of the disk and by observing that dt1 > 0 for dθ > 0 and dt2 > 0 for dθ < 0, one gets
4
Then, the time difference is
t1
=
2πr c
+
2πr2ω c2
t2
=
2πr c
2πr2 c2
ω
.
t1
t2
=
4πr2ω c2 .
(19) (20)
4 Coordinate velocity of light
The analogy with radial motion gives simpler calculations. In this case, the metric becomes
ds2 =
ω2r2 1 c2
c2dt2 dr2.
(21)
Considering a photon which directed from the center O to a point infinitely near, the condition of null geodesics ds = 0 permits to obtain that temporal coordinate required for this as
cdt =
dr .
1
ω2r2 c2
(22)
The photon on the rim corresponds to
If
ωr c
1,
one
gets
r
ˆ ct =
0
dr
1
ω2r2 c2
(23)
t
r c
+
ω2r3 6c3
+
...
(24)
for the coordinate time.
Therefore, if one considers the laboratory clock, the photons flight lasts
longer
than
r c
.
In
fact,
from
1
ω2r2 c2
c2dt2 dr2 = 0
(25)
one sees that the coordinate velocity of light decreases with the distance from the center
dr dt
=
c
1
ω2r2 c2
.
(26)
Of course, this is an apparent effect due to time dilation along the path but the local velocity of light is always c. Indeed,
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dr = dr dt = c dτ dt dτ
1
ω2r2 c2
1
= c.
1
ω2r2 c2
(27)
5 Coriolis time delay
The Coriolis force has a general relativistic explanation. In [29], a general relativistic analysis permits indeed to determine the force on an observer moving with a uniform velocity in a coordinate system which rotates with a constant angular velocity ω = 0 as
→F
=
m→ω
(−→ω
→r ) 1
+ 2m
v2 c2
(−→ω
→v )
,
(28)
where →v is the velocity of the observer in the rotating system, →v = →v +(−→ω ∧ →r )
is the total velocity of the observer relative to the non-rotating system, and m
is the total mass of the observer in the rotating system, see [29] for details. For
non-relativistic velocities (v ≪ c) Eq. (28) reduces to [29]
→F ≃ m→ω ∧ (−→ω ∧ →r ) 2m (−→ω ∧ →v ) ,
(29)
where
→F c = m→ω ∧ (−→ω ∧ →r )
(30)
is the centrifugal force on the observer and
→F C = 2m ∧ (−→ω ∧ →v )
(31)
is the Coriolis force. Now, one considers the local Lorentz gauge of the rotating observer [30]. This is the gauge in which the space-time is locally flat and the distance between any two points is given simply by the difference in their coordinates in the sense of Newtonian physics, [30]. In this gauge, “gravitation” manifests itself by exerting “tidal forces” on the masses. Equivalently we can say that there is a “gravitational” potential [30]
V = →v · (−→ω ∧ →r ) ,
(32)
which generates the the Coriolis “tidal force” of Eq. (31), and that the motion of the test mass is governed by the Newtonian equation
→¨r = ▽ V.
(33)
As we are considering a circular motion on the rotating platform, we simply have V = vωr. Thus, one considers the time dilatation in the weak field approximation by using a well known formula which connects the Newtonian approximation with the linearized GTR [27]
dτ =
(1
+
2V c2
)dt
1
+
V c2
dt =
1
+
vωr c2
dt.
(34)
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The time delay between the beam splitter and the light rays is
dτ1 =
1
+
vωr c2
dt =
1
+
vωr c2
rdθ v
=
r v
+
ωr2 c2
dτ2 =
1
vωr c2
dt =
1
vωr c2
rdθ v
=
r v
ωr2 c2
dθ.
The two Eqs. (35) can be integrated as
τ1 = ´
r v
+
ωr2 c2
=
2πr v
+
2πr2ω c2
0
Thus,
τ2 = ´
r v
ωr2 c2
=
2πr v
2πr2 c2
ω
.
0
τ1
τ2
=
4πr2ω c2 .
(35) (36) (37)
6 Conclusions
In this paper some considerations about the Sagnac experiment have been made. It has been shown that, by considering the rotating metric and by imposing the cancellation of the line element, one has an unexceptionable explanation only from the mathematical point of view. In this way, it seems that the speed of light varies by c± ωr in one or the other direction around the disk. Instead, as it happens for example in Rindler or Schwarzschild metric, the apparent variation of the speed of light is a consequence of time dilation. For this reason, it seems that the physics of the experiment is clearer by using the "gravitational" Coriolis time dilation.
7 Acknowledgements
The Authors thank an unknown Referee for useful comments. This work has been supported financially by the Research Institute for Astronomy and Astrophysics of Maragha (RIAAM).
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