zotero/storage/KIDW8J4C/.zotero-ft-cache

October 2021

arXiv:2110.02078v1 [physics.gen-ph] 4 Oct 2021

Something is wrong in the state of QED

Oliver Consa
Department of Physics and Nuclear Engineering, Universitat Politècnica de Catalunya Campus Nord, C. Jordi Girona, 1-3, 08034 Barcelona, Spain
E-mail: oliver.consa@gmail.com
Quantum electrodynamics (QED) is considered the most accurate theory in the history of science. However, this precision is based on a single experimental value: the anomalous magnetic moment of the electron (g-factor). An examination of the history of QED reveals that this value was obtained in a very suspicious way. These suspicions include the case of Karplus & Kroll, who admitted to having lied in their presentation of the most relevant calculation in the history of QED. As we will demonstrate in this paper, the Karplus & Kroll aﬀair was not an isolated case, but one in a long series of errors, suspicious coincidences, mathematical inconsistencies and renormalized inﬁnities swept under the rug.

1 Introduction

2 Quantum Field Theory (QFT)

After the end of World War II, American physicists organized a series of three transcendent conferences for the development of modern physics: Shelter Island (1947), Pocono (1948) and Oldstone (1949). These conferences were intended to be a continuation of the mythical Solvay conferences. But, after World War II, the world had changed.
The launch of the atomic bombs in Hiroshima and Nagasaki (1945), followed by the immediate surrender of Japan, made the Manhattan Project scientists true war heroes. Physicists were no longer a group of harmless intellectuals; they became the powerful holders of the atomic bomb’s secrets. They were militarized and their knowledge became a state secret. There was a positive aspect: the US government created the Atomic Energy Commission (AEC) and appointed Oppenheimer as its chief advisor. Former members of the Manhattan Project took control of universities and research centers. They received generous grants from the government that allowed them to invest in expensive experimental resources, such as particle accelerators, supercomputers, or atomic explosion tests. But no one considered the risk to the future of science.
Former members of the Manhattan Project now enjoyed unlimited credibility. Their hypotheses were automatically accepted and no one could refute his theories. Their calculations and experimental data were subject to military secrecy, and the cost of the equipment necessary to conduct the experiments was prohibitive for the rest of the international scientiﬁc community. Consequently, the calculations and experiments could no longer be reproduced independently. Those who accepted the their hypotheses were rewarded with good jobs at research centers and universities, while those who criticized their work were rejected and ostracized. The inevitable consequences of this new situation will soon become apparent.

2.1 Nature is absurd
The acceptance of quantum mechanics meant the acceptance of strange explanations, such as the wave-corpuscle duality, the uncertainty principle or the collapse of the wave function.
With the quantization of the electromagnetic ﬁeld, these strange explanations became even more confusing, including the polarization of the quantum vacuum, electrons and photons interacting with their own electromagnetic ﬁelds, particles traveling back in time, the emission and reception of virtual photons, or the continuous creation and destruction of electron-positron pairs in a quantum vacuum.
Feynman summarized this new paradigm quite clearly: “It is whether or not the theory gives predictions that agree with experiment. It is not a question of whether a theory is philosophically delightful, or easy to understand, or perfectly reasonable from the point of view of common sense. The theory of quantum electrodynamics describes Nature as absurd from the point of view of common sense. And it agrees fully with experiment. So I hope you can accept Nature as She is: absurd. I’m going to have fun telling you about this absurdity, because I ﬁnd it delightful. Please don’t turn yourself oﬀ because you can’t believe Nature is so strange.” [1]
2.2 The problem of inﬁnities
After the success of the Dirac equation in 1928, quantum mechanics theorists attempted to quantify the electromagnetic ﬁeld by creating the quantum ﬁeld theory (QFT). Unfortunately, QFT was a complete failure since any attempted calculation under this theory resulted in an inﬁnite number.
The only solution the proponents could devise was to simply ignore these inﬁnities. Many methods can be used to ignore inﬁnities, but the primary ones are:
• Substitution: replacing a divergent series with a speciﬁc ﬁnite value that has been arbitrarily chosen (for

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example, the energy of an electron).

3 Shelter Island (1947)

• Separation: separating an inﬁnite series into two components, one that diverges to inﬁnity and another that converges to a ﬁnite value. Eventually, the inﬁnite component is ignored and only the ﬁnite part remains.
• Cut-oﬀ: focusing on an arbitrary term in the evolution of a series that diverges to inﬁnity and ignoring the rest of the terms of the series.

All these techniques are illegitimate from a mathematical perspective, as demonstrated by Dirac: “I must say that I am very dissatisﬁed with the situation because this so-called ’good theory’ does involve neglecting inﬁnities which appear in its equations, ignoring them in an arbitrary way. This is just not sensible mathematics. Sensible mathematics involves disregarding a quantity when it is small – not neglecting it just because it is inﬁnitely great and you do not want it!. ” [59]
This technique of ignoring inﬁnities is called renormalization. Feynman also recognized that this technique is not mathematically legitimate: “The shell game that we play is technically called ’renormalization’. But no matter how clever the word, it is still what I would call a dippy process! Having to resort to such hocus-pocus has prevented us from proving that the theory of quantum electrodynamics is mathematically self-consistent. It’s surprising that the theory still hasn’t been proved self-consistent one way or the other by now; I suspect that renormalization is not mathematically legitimate.” [1]
As an example of the use of these renormalization techniques we can look at the calculation of the Casimir eﬀect. [3] The equation of the Casimir eﬀect depends on the Riemann function.

Fc A

=

d< da

E A

>

=

−

cπ2 2a4

ζ(−3)

=

cπ2 20a4

ζ(−1)

(1)

However, the Riemann function is deﬁned only for positive values, since for negative values the Riemann function diverges to inﬁnity. The Riemann function of -1 is equal to the sum of all positive integers. Applying a renormalization technique, the Indian mathematician Ramanujan calculated that the sum of all positive integers is not inﬁnity but -1/12. [2]

3.1 The Shelter Island conference
From June 2 to 4, 1947, the ﬁrst international physics conference after World War II was held at Shelter Island. The conference brought together 24 physicists from the Manhattan Project, including Bethe, Bohm, Breit, Feynman, Kramers, Lamb, von Neumann, Pauling, Rabi, Schwinger, Teller, Uhlenbeck, Weisskopf and Wheeler. Oppenheimer acted as congress master of ceremonies. The participants were received as celebrities, and the conference made a signiﬁcant impact in the press. Despite high expectations, the conference ended in disappointment.
Fig. 1: Shelter Island Conference participants
Two important experimental measures were presented at the Shelter Island conference: the Lamb shift and the anomalous magnetic moment of the electron. Lamb [4] presented an experiment that showed that the 2S1/2 and the 2P1/2 energy levels of the hydrogen atom were not identical; instead they diﬀered by about 1000 MHz. Rabi’s team [5] presented a 0.1% anomaly in the hyperﬁne structure of hydrogen. Later, Breit [6] interpreted this anomaly as the anomalous magnetic moment of the electron (g-factor).
These two measurements contradicted the Dirac equation. Meeting participants assumed that Dirac’s theory of the electron was incomplete and proposed that these eﬀects were due to the quantization of the electromagnetic ﬁeld. It was also assumed that these discrepancies could be calculated using the QFT and that the inﬁnities of this theory could be corrected using renormalization techniques. This was the origin of Quantum Electrodynamics (QED).

ζ(−1) = ∞ n = 1 + 2 + 3 + 4 + 5 + ... = −1

(2)

n=1

12

And this is precisely the value that is used in the equation of the Casimir eﬀect.

Fc A

=

cπ2 20a4

−1 12

=

−

cπ2 240a4

(3)

If Dirac had been at the Shelter Island conference, the story of the QED would have been very diﬀerent, as he said: "Renormalization is just a stop-gap procedure. There must be some fundamental change in our ideas, probably a change just as fundamental as the passage from Bohr’s orbit theory to quantum mechanics. When you get a number turning out to be inﬁnite which ought to be ﬁnite, you should admit that there is something wrong with your equations, and not hope that you can get a good theory just by doctoring up that number.” [65]

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3.2 Bethe’s calculation of the Lamb Shift

On the train trip home after the conference ended, Bethe starred in one of the most epic moments in the history of theoretical physics. As recalled by Bethe: "I said to myself, well, let’s try to calculate that Lamb shift. And indeed, once the conference was over, I traveled by train to the General Electric research lab. And on the train I ﬁgured out how much that diﬀerence might be.” [67]
The paper published by Bethe in 1947 [7] was a short three pages where he proposed this equation for the Lamb shift.

Wns

=

8 3π

e2

3
Ry

c

Z4 n3

K ln < En − Em >Av

(4)

Where Ry is the ionization energy of the ground state of hydrogen (13.6 eV) and < En − Em >Av is the average excitation energy for the 2s state of hydrogen.
In this equation, K is a series that diverges to inﬁnity. Bethe decided to apply renormalization by substituting this inﬁnite value for the ﬁnite value of the electron’s energy (K = mc2). There is no physical justiﬁcation for making this change, except that when applying that change, the theoretical value was in good agreement with the new experimental value.

Wns = 136 ln

K kp

= 136 ln

mec2 17.8 Ry

= 1040 Mhz

(5)

According to the paper, "The average excitation energy has been calculated numerically by Dr. Stehn and Miss Steward.”. [7] They proposed a value of 17.8 Ry (242 eV), a value that Bethe considered "an amazingly high value." [7] Informally, ln(kp) is also known as ’Bethe logarithm’.
As you can see, Bethe’s fantastic calculation is based on data that was calculated later, so Bethe could not have known it on his train journey. His calculation included this value that we suspect that was entered ad hoc to match the theoretical value with the experimental value. In the ﬁeld of physics, this trick is known as a ’fudge factor’.

3.3 Schwinger’s numerology

A few months after Bethe calculated the value of the Lamb shift, Schwinger devised an even more epic calculation. He published a one-page paper [8] with a simple theoretical value for the electron g-factor, just α/2π .

g

=

1

+

α 2π

(6)

 

g (theor) = 1.00116

 g (exp) = 1.00119

(7)

This value, known as the "Schwinger factor", was in good agreement with the experimental value published by Kush and Foley [9]. Schwinger did not explain how he got that

value because "a paper dealing with the details of this theory and its applications is in course of preparation." [8]
The Schwinger factor had a signiﬁcant impact on the scientiﬁc community due to its simplicity and accuracy. Everyone waited expectantly for the fabulous new theory he had used to calculate this factor. Schwinger’s theory must signify a revolution in modern physics. But, the days passed, and Schwinger did not publish his theory.
Why did not he publish this long-awaited theory? We suspect that Schwinger did not publish the theory because he had no theory. How did he obtain such a spectacular result without a theory? We suspect that he used a technique known as numerology. Schwinger assumed that the g-factor should be directly related to the ﬁne structure constant (α), which has an approximate value of 0.7%. Dividing this value by 6 provides an approximate value of 0.1%, which is the value obtained by Rabi [5]. And 2π is about 6.
4 Pocono (1948)
4.1 The Pocono conference
The Pocono conference took place from March 30 to April 2, 1948. This conference was attended by the same participants as the Shelter Island conference, as well as three of the greatest physicists of the time: Bohr, Dirac and Fermi. As with the Shelter Island conference, the expectations were high due to recent progress from Bethe and Schwinger. And as in the Shelter Island conference, the results were again disappointing.
The conference expectations were focused on Schwinger’s presentation. Everyone hoped that he would ﬁnally explain the elegant way in which the Schwinger factor had been calculated.
But Schwinger’s presentation lasted for ﬁve unbearable hours and comprised a series of complex, totally incomprehensible equations. Oppenheimer expressed his displeasure: “others gave talks to show others how to do the calculation, while Schwinger gave talks to show that only he could do it.” [68] Gradually, the attendees left the presentation until only Bethe and Fermi remained. The overall feeling was one of disappointment, as it was clear that Schwinger’s theory was not based on an elegant solution.
The next day, Feynman presented his theory, explaining for the ﬁrst time his famous Feynman diagrams. However, the attendees did not respond positively to this presentation. Feynman was convinced of the validity of his calculations simply because they produced the correct results.
Bethe remembers the conference like this: “At Pocono, Schwinger and Feynman, respectively presented their theories. (...) Their theories seemed to be totally diﬀerent. (...) Schwinger’s was closely connected to the known quantum electrodynamics, so Niels Bohr, who was in the audience, immediately was convinced this was correct. And then Feynman came with his completely new ideas, which

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among other things involved positrons going backwards in time. And Niels Bohr was shocked, that couldn’t possibly be true, and gave Feynman a very hard time.” [66]
Feynman’s recollection of the conference is also enlightening: “This meeting at Pocono was very exciting, because Schwinger was going to tell how he did things and I was to explain mine. (...). We could talk back and forth, without going into details, but nobody there understood either of us. (...) When he tried to explain his theory, he encountered great diﬃculty. (...) As soon as he would try to explain the ideas physically, the wolves would descend on him, he had great diﬃculty. Also, people were getting more and more tired (...) I didn’t have a mathematical scheme to talk about. Actually I had discovered one mathematical expression, from which all my diagrams, rules and formulas would come out. The only way I knew that one of my formulas worked was when I got the right result from it. (...) I said in my talk: "This is my mathematical formula, and I’ll show you that it produces all the results of quantum electrodynamics." immediately I was asked: "Where does the formula come from?’ I said, "It doesn’t matter where it comes from; it works, it’s the right formula!" "How do you know it’s the right formula?" "Because it works, it gives the right results!" "How do you know it gives the right answers?" ’ (...) They got bored when I tried to go into the details. (...) Then I tried to go into the physical ideas. I got deeper and deeper into diﬃculties, everything chaotic. I tried to explain the tricks I had employed. (...) I had discovered from empirical rules that if you don’t pay attention to it, you get the right answers anyway, and if you do pay attention to it then you have to worry about this and that.” [69]
After the disappointing explanations of Schwinger and Feynman, the scientists returned home, aware of the need for a new uniﬁed QED theory that could elegantly explain Bethe’s Lamb shift results and the Schwinger factor for the anomalous magnetic moment of the electron.
Upon his return to Princeton, Oppenheimer received a paper from a Japanese physicist named Tomonaga with a third QED theory. Now, there were three QED theories, and all of them were inconsistent and incompatible with one other.
4.2 Dyson’s series
After the Pocono meeting, the physics community searched for a uniﬁed and covariant QED theory. The person in charge of addressing this problem was a young English scientist named Dyson. He managed to reconcile the three QED theories in his paper “The Radiation Theories of Tomonaga, Schwinger, and Feynman.” [10]
Dyson proposed that the Heisenberg S-matrix could be used to calculate the electron’s g-factor, transforming it into a series called the Dyson’s series [11]. The Dyson’s series was an inﬁnite series of powers of alpha, where the ﬁrst coeﬃcient was precisely the Schwinger factor, and where each

coeﬃcient could be calculated by solving a certain number of Feynman diagrams.

α

α2

α3

α4

α5

g = 1+C1 π +C2 π +C3 π +C4 π +C5 π ... (8)

Dyson’s theory based on Feynman diagrams provided the solution his colleagues were waiting for. The enthusiasm returned to the American scientiﬁc community.

4.3 Internal criticism
However, not all scientists were excited about Feynman’s and Dyson’s results. The primary critic of this new QED theory was Dirac: “How then do they manage with these incorrect equations? These equations lead to inﬁnities when one tries to solve them; these inﬁnities ought not to be there. They remove them artiﬁcially. (...) Just because the results happen to be in agreement with observations does not prove that one’s theory is correct.” [58]
Another critic was Oppenheimer, as Dyson relates: “When after some weeks I had a chance to talk to Oppenheimer, I was astonished to discover that his reasons for being uninterested in my work were quite the opposite of what I had imagined. I had expected that he would disparage my program as merely unoriginal, a minor adumbration of Schwinger and Feynman. On the contrary, he considered it to be fundamentally on the wrong track. He thought adumbrating Schwinger and Feynman to be a wasted eﬀort, because he did not believe that the ideas of Schwinger and Feynman had much to do with reality. I had known that he had never appreciated Feynman, but it came as a shock to hear him now violently opposing Schwinger, his own student, whose work he had acclaimed so enthusiastically six months earlier. He had somehow become convinced during his stay in Europe that physics was in need of radically new ideas, that this quantum electrodynamics of Schwinger and Feynman was just another misguided attempt to patch up old ideas with fancy mathematics.” [61]
According to Dyson, Fermi also did not agree with this new way of conducting science: “When Dyson met Fermi, he quickly put aside the graphs he was being shown indicating agreement between theory and experiment. His verdict, as Dyson remembered, was “There are two ways of doing calculations in theoretical physics. One way, and this is the way I prefer, is to have a clear physical picture of the process you are calculating. The other way is to have a precise and self-consistent mathematical formalism. You have neither.” When a stunned Dyson tried to counter by emphasizing the agreement between experiment and the calculations, Fermi asked him how many free parameters he had used to obtain the ﬁt. Smiling after being told “Four,” Fermi remarked, “I remember my old friend Johnny von Neumann used to say, with four parameters I can ﬁt an elephant, and with ﬁve I can make him wiggle his trunk.” There was little to add.” [63]

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Feynman’s response to these criticisms is well known: “Shut up and Calculate!” [1]
5 Oldstone (1949)

It was assumed that the diﬀerence between the theoretical and experimental values of the Lamb shift was due to relativistic corrections. These corrections were calculated by Baranger in 1951 [15]

5.1 The Oldstone conference
From April 11 to 14, 1949, a third conference was held at Oldstone, with the same participants as the Shelter Island and Pocono conferences. As on the previous occasions, the Oldstone conference began with great expectations, this time based on Dyson’s advances. As with the previous conferences, the results were disappointing.
The star of the Oldstone conference was Feynman, who used his immense charisma to present Dyson’s theory as the deﬁnitive formalism of the QED theory. From that moment on, Feynman’s diagrams became a popular tool among American physicists, and Feynman became the leader of this new generation of scientists.
In parallel to the QED consolidation, the conference presented important experimental results on subatomic particles that were called pi-mesons or pions. These particles had been discovered thanks to the new synchrocyclotron particle accelerator at the University of Berkeley. Interest in QED rapidly declined due to its extreme complexity and lack of practical utility, while the pions became the primary focus. As a result, Oppenheimer decided not to convene any further QED conferences; instead, he created the International Conference of High Energy Physics (ICHEP).
5.2 Feynman diagrams in QCD
New research in high energy physics resulted in Quantum Chromodynamics (QCD), the Electroweak Theory (EWT) and the Standard Model of particle physics. All these developments relied heavily on the use of Feynman diagrams. However, the Feynman diagrams are only valid when the coupling constant has a very low value. Obviously if α > 1, the Dyson’s series would diverge.
But, in the case of fermions, the coupling constant is greater than one, so the Dyson’s series would diverge. This means that it is not mathematically legitimate to use Feynman diagrams for these calculations.
In 1951, Feynman himself warned Fermi of this problem: ”Don’t believe any calculation in meson theory that uses a Feynman diagram.” [70]

∆W = α4Ry 1 +

11

ln 2 −

= 6.894 Mhz

(10)

128 2

Baranger obtained a theoretical Lamb shift value of 1058.3 MHz, in good agreement with the new the experimental value of 1061 ± 2 Mhz.

6 Fourth-order correction (1950-1957)
6.1 The Kroll & Karplus calculation
In 1949, Gardner and Purcell obtained a new experimental result for the g factor of 1.001,146 [12]. With this new experimental value, the Schwinger factor was no longer considered accurate. Feynman seized this new crisis as an opportunity to demonstrate the validity of Dyson’s reformulation of the QED, where the renormalization of inﬁnities could be performed consistently.
In 1950, Karplus and Kroll [13] completed these complex calculations and published a value of -2,973 for the second coeﬃcient in the Dyson series.



α

α2

 

g = 1 + 2π − 2.973 π g (theor) = 1.001, 147
g (exp) = 1.001, 146

(11)

For the second time, the new theoretical value was in good agreement with the new experimental value.
As indicated in the paper, “The details of two independent calculations which were performed so as to provide some check of the ﬁnal result are available from the authors.” [13] The calculations had been performed independently by two teams of mathematicians who had obtained the same result. Therefore, it was impossible that there were any errors in the calculations. Nor was it possible to imagine that a theoretical result that was identical to the experimental result could have been achieved by chance.
This was the deﬁnitive test. QED had triumphed. Feynman’s prestige dramatically increased and he began to be mentioned as a candidate for the Nobel Prize.

6.2 Dyson’s divergence

5.3 Improved Lamb shift calculation

In 1950, Bethe [14] improved the "Bethe logarithm" from 17.8 Ry to 16.646 Ry and incorporated the new factors of Kroll, Feynman, French and Weisskopf into the Lamb shift calculation. With these changes, he obtained an improved value of 1052 Mhz.

Wns

=

α3 3π Ry

ln

mc2 16.646

Ry

−

ln

2

+

5 6

−

1 5

(9)

In 1952, two years after this great success, Dyson published a paper entitled “Divergence of Perturbation Theory in Quantum Electrodynamics” where he states: “An argument is presented which leads tentatively to the conclusion that all the power-series expansions currently in use in quantum electrodynamics are divergent after the renormalization of mass and charge.” [16]
The creator of the QED theory stated that his Dyson’s series was divergent. As Dyson admitted: "That was of course

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a terrible blow to all my hopes. I really meant that this whole program made no sense." [62] After the publication of this paper, Dyson moved to England, abandoned this line of research and dedicated the rest of his career to other areas of physics.
Surprisingly, Dyson’s claim that the series was divergent did not diminish QED’s credibility.
6.3 The Witch-Hunt
In 1949, the USSR had obtained the atomic bomb thanks to information provided by Fuchs, a Manhattan Project researcher with communist sympathies. Senator McCarthy began a witch hunt where espionage accusations became widespread among the American scientiﬁc community. Oppenheimer was accused of espionage and treason. He was tried and found not guilty, but his position as chief advisor at the AEC was removed.
Now the scientists’ own lives were in jeopardy. Deﬁnitely, 1952 was a bad year to admit the complete failure of the main theoretical research program in modern physics.
The witch hunt ended in 1957, when the Russians sent the Sputnik satellite into space and the US government realized that it needed scientists to create NASA and win the space race.

enough. (...) it was refereed and published and was a famous paper and now it’s an infamous paper.” [64]
Feynman’s version of these events does not fully correspond to reality: “It took two ‘independent’ groups of physicists two years to calculate this next term, and then another year to ﬁnd out there was a mistake - experimenters had measured the value to be slightly diﬀerent, and it looked for a while that the theory didn’t agree with experiment for the ﬁrst time, but no: it was a mistake in arithmetic. How could two groups make the same mistake? It turns out that near the end of the calculation the two groups compared notes and ironed out the diﬀerences between their calculations, so they were not really independent”. [1]

6.5 Petermann’s solution
Petermann [20] detected an error in the Kroll and Karplus calculations (one that no one had detected in the seven years since the article was published). He made the correct calculation and obtained a result of -0.328, which was almost ten times lower than the previous calculation.



α

α2

 

g = 1 + 2π − 0.328 π g (theor) = 1.001, 159, 6
g (exp) = 1.001, 165

(12)

6.4 The infamous paper
In 1956, Franken and Liebes [17] published new, more precise experimental data that provided a very diﬀerent g-factor value (1.001,165). This value was higher than the Schwinger factor, so the value of the second coeﬃcient that had been calculated by Kroll and Karplus not only did not improve the Schwinger factor; it made the calculation worse.
With the new experimental data, the value of the second coeﬃcient of the series should have been +0.7 instead of -2.973. The diﬀerence between these values was huge and unjustiﬁable. The probative force of QED was upended. In addition, there was no explanation for why Kroll and Karplus’s calculation provided the exact expected experimental value when that value was incorrect. It was evident that the QED calculations had matched the experimental data because they were manipulated. It was a fraud, a scandal.
Karplus and Kroll confessed that they had not independently reached the same result; instead, they had reached a consensus result. Therefore, it was possible that there were errors in the calculation.
According to Kroll: “Karplus and I carried out the ﬁrst major application of that program, to calculate the fourth order magnetic moment, which calculation subsequently turned out to have some errors in it, which has been a perpetual source of embarrassment to me, but nevertheless the paper I believe was quite inﬂuential. (...) The errors were arithmetic (...) We had some internal checks but not nearly

The same error was independently detected by Sommerﬁeld [21]. Once again, two independent calculations provided the same theoretical value.
For the third time, the new theoretical value was in good agreement with the new experimental value.
7 The Unpublished Feynman diagram IIc
7.1 Karplus and Kroll’s paper
At this point, we have doubts about everything that was reported, so we reviewed the original article published by Kroll and Karplus as well as the corrections of Petermann and Sommerﬁeld published seven years after.
Karplus and Kroll’s paper consists of 14 pages full of complex mathematical calculations [13]. On the second page of the document, the authors indicate that to obtain the coeﬃcient it is necessary to calculate 18 Feynman diagrams grouped in ﬁve groups (I, II, III, IV and V). However, on pages 3 and 4, they argue that groups III, IV and V are not necessary.
Therefore, it is only necessary to calculate seven Feynman diagrams, identiﬁed as I, IIa, IIb, IIc, IId, IIe, IIf. A lot of calculations are done between pages 4 and 11 that only serve to show that diagrams IIb and IIf are not necessary either. Therefore, it is only necessary to calculate ﬁve Feynman diagrams (I, IIa, IIc, IId, IIe).
The calculation of diagrams IIe (0.016) and IId (-0.090) are performed on pages 11 and 12 respectively. It follows

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is not possible to say anything more about the calculation of diagram IIc because the complete calculation was never published.

7.2 Petermann’s numerical calculation

Fig. 2: Feynman diagrams for the fourth-order corrections

that: “The expressions for I, IIa and IIc become successively more complicated and very much more tedious to evaluate and cannot be given in detail here.” [13] In other words, the complete calculation of three of the ﬁve diagrams was never published. On page 13, the results of the three remaining diagrams are shown (I = -0.499, IIa = 0.778 and IIc = -3.178). Finally, page 14 of the paper presents the "Summary of Results" with the results of each of the ﬁve diagrams.

C2 = I + IIa + IIc + IId + IIe = −2, 973 (13)

I

IIa

IIc

IId

IIe Total

-0.499 0.778 -3.178 -0.090 0.016 -2.973

Table 1: Values of the ﬁve Feynman diagrams.

Petermann was the ﬁrst person to identify an error in the original calculation of Karplus and Kroll. He performed a numerical analysis of the ﬁve Feynman diagrams. He found that the solution of diagram IIc was clearly wrong, since its value was outside the limits. The rest of the diagrams were within limits: “The numerical results for the terms I, IIa, IIc, IId, IIe in the work by Karplus and Kroll have been checked by rigorous upper and lower bounds. Whereas every other term fell well between these bounds, agreement could not be obtained for diagram IIc. (...) The numerical value for this term has been found to satisfy IIc = -1.02 +/- 0.53.” [18]
Petermann published a second paper where he adjusted his calculations: ”the diagram IIc is found to satisfy IIc = -0.60 +/- 0.11 in contradiction with the value -3.18 given by the previous authors.” [19]
Between the publication of these two papers, Petermann communicated privately to Sommerﬁeld the result of another calculation: "Petermann has placed upper and lower bounds on the separate terms of Karplus and Kroll. He ﬁnds that their value for IIc does not lie within the appropriate bounds. Assuming the other terms to be correct, he concludes that the result is -0.53 +/- 0.37.” [21]
Petermann worked for three months following a numerical methodology that allowed him to narrow the margin of error in diagram IIc. Surprisingly, fourteen days after his third numerical calculation, he made an unexpected change in his methodology and published the exact analytical calculation, with no margins of error.
The articles published by Petermann on the calculation of the Feynman diagram IIc are summarized in the following table:

Diagrams IId and IIe were the only diagrams whose calculations are included in the document; however, its values were completely irrelevant. Diagrams I and IIa practically cancel each other out. IIc was the dominant diagram and consisted of four components:

I Ic

= − 323 24

+

31 π2 − 9

49 π2ln(2) + 6

107 ζ(3) = −3, 178 4

(14)

Constant π2

π2ln2 ζ(3) Total

-13,458 33,995 -55,868 32,153 -3,178

Date

IIc

Method Publication

28/5 -1.02 +/- 0.53 Numerical Nuclear Phys. 3

1/7 - 0.53 +/- 0.37 Numerical Phys. Rev. 107, Note added in proof.

3/8 -0.60 +/- 0.11 Numerical Nuclear Phys. 5

17/8

-0,564

Analytical Helvetica Physica

Acta 30

Table 3: Petermann’s publications.

Table 2: Value of the four components of Feynman diagram IIc. 7.3 Sommerﬁeld and the Green’s functions

The four components of IIc have abnormally high values After the publication of the new experimental value by (-13, 34, -55 and 32) which surprisingly compensate for each Franken and Liebes [17], Schwinger commissioned a other, resulting in -3,178, an order of magnitude lower. It 22-year-old student named Sommerﬁeld to redo the Kroll and

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Karplus calculations. Schwinger proposed using his own method based on Green’s functions instead of using Feynman diagrams. According to Sommerﬁeld: "Julian assigned us three problems, one of which involved the anomalous magnetic moment (...). At my meeting with him, he suggested that I continue the calculation of the anomalous magnetic moment to the next fourth order (...). Schwinger wanted me to use the other method, while respecting gauge invariance at every step. Many years later Roy Glauber told me that the faculty was not entirely happy that a graduate student had been given such a problem." [23]
In May 1957, Sommerﬁeld sent a two-page paper to the Physical Review Journal where he published his results:

other but not with Karplus and Kroll. We agreed to cite each other’s work when published. However, Schwinger and Kallen had had a somewhat acrimonious discussion (...) and Kallen had forbidden Petermann to mention my work. Petermann’s apology to me was profuse.". [23] Although the paper was signed by a single author, Petermann acknowledges that the result was obtained by consensus: “The new fourth order correction given here is in agreement with: (a) The upper and lower bounds given by the author. (b) A calculation using a diﬀerent method, performed by C. Sommerﬁeld. (c) A recalculation done by N. M. Kroll and collaborators.”. [20] Petermann’s ﬁnal result was identical to the Sommerﬁeld’s result published three months earlier.

C2

=

197 144

+

1 π2 12

−

1 π2ln(2) + 2

3 ζ(3) 4

=

−0, 328

(15)

Sommerﬁeld’s paper does not include the calculations performed, but the author states that: “The present calculation has been checked several times and all of the auxiliary integrals have been done in at least two diﬀerent ways.” [21] As a guarantee that the calculations were correct.
He also states that: “The discrepancy has been traced to the term I y IIc of Karplus and Kroll.” [21] But this statement about the origin of the error cannot be deduced from Sommerﬁeld’s calculations, since he used Green’s functions instead of Feynman diagrams.
In 1958 Sommerﬁeld published the full calculation of the g-factor calculations in an extensive 32-page paper as part of his doctoral thesis [22]. He used Green’s functions instead of Feynman diagrams. Then, the calculation of the enigmatic Feynman diagram IIc does not appear in his paper.
As Schwinger states: “Interestingly enough, although Feynman-Dyson methods were applied early [by Karplus and Kroll], the ﬁrst correct higher order calculation was done by Sommerﬁeld using [my] methods.”. [66] In the third volume of "Particles, Sources, and Fields" published in 1989 [24], Schwinger devoted more than 60 pages to a detailed calculation of the second coeﬃcient of Dyson series getting exactly the same result. But, once again, using Green’s functions instead of Feynman diagrams.

C2 = I + IIa + IIc + IId + IIe = −0, 328 (16)

I

IIa

IIc

IId

IIe Total

-0.467 0.778 -0.564 -0.090 0.016 -0.328

Table 4: Corrected values of the ﬁve Feynman diagrams.

I Ic

=

67 −
24

+

1 π2 18

+

1 π2ln(2) 3

−

1 ζ(3) 2

=

−0,

564

(17)

The following table compares the calculations of the four

components of the Feynman IIc diagram made by Karplus

and Kroll (Equation 14) with the calculations made by Peter-

mann (Equation 17).

K&K P&S Diﬀ.

Const. -13,458 -2,791 10,667

π2 33,995 0,548 -33,447

π2 ln(2) -55,868 2,280 58,148

ζ(3) 32,153 -0,601 -32,754

Total -3,178 -0,564 2,614

Table 5: Comparative components of Feynman diagram IIc.

The corrections are huge, one or two orders of magnitude for each component of diagram IIc. We cannot know the origin of these discrepancies because the correction calculations were also not published.
7.5 Smrz & Uleha

7.4 Petermann’s deﬁnitive correction
The deﬁnitive solution to the problem was presented in 1957 by Petermann in a paper published in the Swiss journal Helvetica Physica Acta [20].
The article was signed by a single author due to an internal conﬂict between the researchers. As Sommerﬁed recalls: "In the meantime Schwingerian Paul Martin had gone to the Niels Bohr Institute in Copenhagen and had spoken to Andre Petermann, a postdoc with the Swedish theoretician Gunnar Kallen. Martin told Petermann about my work (...) In the end, however, after both of our calculations were completely ﬁnished they were in agreement with each

In 1960, Smrz & Uleha published a short paper of two pages where the situation generated in 1957 by Petermann’s correction is explained. The authors states that they performed an independent calculation of the Feynman IIc diagram and obtained exactly the same result as Petermann. “Since the considerable diﬀerence between the original value of the magnetic moment (Karplus & Kroll [13]) and the values calculated later (Petermann [20]) originates in the calculation of the contribution from the third diagram, only the value of this contribution was determined by the standard technique and the above regularization in the infra-red region. The contribution from the third diagram (-0.564) is in complete agreement with Petermann’s value.” [26]

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Unfortunately when looking for the reference of the work with the calculations, it has not been published either: "Smrz P.: Diploma thesis, Faculty of Tech. and Nucl. Physics, Prague 1960, unpublished." [26]
7.6 Terentiev
In 1962, Terentiev published a long paper of 50 pages [27]. The paper is only in Russian and there is no English translation. We identify the equation 60 of the paper as the second coeﬃcient of the Dyson’s series, with the same expression and value obtained by Petermann. Analyzing the document, we interpret that this equation is the result of the sum of nine other equations identiﬁed as equations 22, 24, 27, 31, 33, 47, 51, 58 and 59. There are nine equations instead of the ﬁve Feynman diagrams of Karplus and Kroll and none of the these equations correspond to the Feynman Diagram IIc.
7.7 Barbieri & Remiddi
In 1972, Barberi & Remeddi published a long 93-page paper where they performed a recalculation of the Feynman diagrams corresponding to the fourth-order coeﬃcient and conﬁrmed the results obtained by Petermann. The authors give the descriptive name of "Corner Graphs" to the the Feynman IIc. On the speciﬁc calculations, the authors state the following: "Integrations by parts, diﬀerentiations and so on, was done by computer, using the program SCHOONSCHIP of Veltman.” [25] That is, they used a computer program to perform the mathematical calculations, but they did not publish the source code used, so, again, it is not possible to replicate the calculations.
On the ﬁrst page of Barbieri & Remiddi paper there is a reference to Terentiev’s paper, where the authors claim that Terentiev’s results were incorrect and manipulated: “Dispersion relations are used in the Terentiev work only to write down suitable multiple integral representations, which are in general manipulated to get the ﬁnal result, without explicitly evaluating the discontinuities. The problem of infrared divergences has been further overlooked, and many of the intermediate results are wrong, even if somewhat ad hoc compensations make the ﬁnal result correct.” [25]

On the contrary, both enjoyed brilliant careers full of awards and recognition for their professional achievements.
• Karplus and Kroll’s miscalculation was consistent with the experimental value previously published by Gardner and Purcell, even though that experimental value was also wrong.
• The error in the calculation was not reported until seven years after its publication.
• The error in the calculation was detected just when a new experimental value was published by Franken and Liebes. The corrected theoretical value also coincided with the new experimental value.
• Neither the original calculation of the Feynman diagram IIc nor its subsequent correction has been published to date.
• The recalculations of the Feynman diagram IIc of Smrz & Uleha and Barbieri & Remiddi have not been published either.
• The recalculation of Terentiev were revisited ten years later by Remmidi, who claims that these calculations were wrong and manipulated with ad-hoc compensations to make the ﬁnal result correct.

Year 1950 1957 1957 1958
1960 1962
1972

Author Karplus & Kroll
Petermann Sommerﬁeld Sommerﬁeld
Smrz & Uleha Terentiev
Remiddi

Status of calculations
Wrong and Unpublished
Right but Unpublished
Right but Unpublished
Right but using Green’s Functions instead of Feynman Diagrams
Right but Unpublished
Wrong intermediate results with ad hoc compensations to make the ﬁnal result correct
Right but Unpublished Computer calculation

7.8 Summary of the situation
The history of this calculation is surrounded by big errors and inexplicable coincidences.

1989

Schwinger

Right but using Green’s Functions

Table 6: fourth-order coeﬃcient calculation.

• The original calculation of the Feynman diagram IIc published in 1950 was completely wrong.
• Karplus and Kroll stated that the calculation had been performed by two teams independently. This statement was made to give guarantees about the validity of the calculations, and yet it turned out to be false.
• Despite having published a completely wrong result, the prestige of Karplus and Kroll was not aﬀected at all.

8 The Nobel Prize (1965)
8.1 Direct g-factor measurement
In 1953, a research team from the University of Michigan [28] proposed a new type of experiment to calculate the magnetic moment of the electron directly from the precession of the free electron spin. This new technique provided more precise experimental values than the previous techniques that were based on atomic levels.

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In 1961, Schupp, Pidd and Crane carried on the experiment and published a new experimental value of 1.0011609. The experiment was revolutionary because of the measured precision, however, the authors were cautious with their results, presenting large margins of error. The explanation for this strange decision is found in the paper: “In deciding upon a single value for a to give as the result of the experiment, our judgement is that we should recognize the trend of the points (...). The value a=0.0011609, obtained in this way, may be compared with a simple weighted average of the data of Table IV, which is 0.0011627. We adopt the value 0.0011609 but assign a standard error which is great enough to include the weighted average of Table IV, namely ±0.0000020. Finally, we combine with this the estimated systematic standard errors (...). This results in a ﬁnal value of 0.0011609 ± 0.0000024”. [29]

port of the results all the previous cautionary language disappeared. The accuracy of this result was presented as 100 times higher than that of the previous experiment, and the tone of the paper was blunt: “mainly for experimental reasons, we here conclude the 10-year eﬀort of the laboratory on the g factor of the free negative electron.” [30]
Just when QED seemed doomed to disaster, the miracle happened again. This time, the new experimental value was 1, 001, 159, 622 ± 0.000, 000, 027, nearly the same as Petermann’s theoretical value (1,001,159,615).

Fig. 4: Experimental values

Fig. 3: Table IV, the g-factor anomaly calculated for the various electron energies
According to this explanation, the estimated systematic standard error was 0.0000004. If this error had been published, the result would have been 1.0011609 ± 0.0000004, leaving Petermann’s theoretical value outside the margin of error and creating a new crisis in the development of QED.
The authors proposed another possible approach: they averaged the measurements in Table IV, generating a result of 1.0011627 ± 0.0000024. But this alternative result also left out of the margin of error the Petermann’s theoretical value.
Finally, the authors published a meaningless result. Although they published what they considered to be the correct result (1.0011609), they added a margin of error of +0.0000024 to include the average of the actual results. They also added a negative symmetrical margin of error of -0.0000024, without any logical; this was the only way to keep Petermann’s theoretical value within the margin of error.
8.2 The experimenter’s bias
At that time the situation was dramatic again. Predictably, subsequent experiments would discredit the g-factor theoretical value. And after the Kroll and Karplus scandal, the theoretical calculations could not be modiﬁed again to adapt them to the experimental data without completely distorting the QED.
And the moment come in 1963, Wilkinson and Crane published a improved version of the experiment. In the re-

This experimental result is incredibly suspicious. It was obtained after a simple improvement of the previous experiment, and it was conducted at the same University, with the same team, only two years later. It is extremely strange that all the measurements from the previous experiment were outside the range of the new experimental value. Even stranger, the theoretical value ﬁt perfectly within the experimental value. Most disturbing, this value is not correct, as was demonstrated in later experiments.

8.3 The Nobel Prize
In 1965, Drell and Pagels [31] published the ﬁrst calculation of the third coeﬃcient of the Dyson’s series (sixth order correction), that implied solving 72 Feynman diagrams. The result was 0.15, which allowed to slightly improve the theoretical value of the electron g-factor.

 


g

=

1

+

α 2π

−

0.328

α π

2
+ 0.15

α π

3

g (theor) = 1, 001, 159, 617

g (exp) = 1, 001, 159, 622

(18)

For the fourth time, the new theoretical value was in good agreement with the new experimental value. At this point all doubts about QED were cleared and Feynman, Schwinger and Tomonaga were awarded the Nobel Prize in physics in 1965.

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9 Sixth-order Correction (1968-1972)
9.1 Wesley and Rich, preliminary
In 1968, Rich [34] reevaluated the Wilkinson’s experiment and obtained a diﬀerent result. Other researchers found more errors in the experiment which allowed diﬀerent interpretations of the results. It became clear that the Wilkinson’s experiment had to be repeated to ﬁx these discrepancies.
In 1970, Rich and Wesley [33] repeated Wilkinson’s experiment, ﬁxing the detected ambiguities and obtaining a result higher that the previous one.
The same year, Brodky & Drell [32] recalculated the sixth-order factor and obtained a value of +0.55, three times higher that the previous value.

 


α g = 1 + 2π − 0.328

α π

2
+ 0.55

α π

3

g (theor) = 1, 001, 159, 644

g (exp) = 1, 001, 159, 644

(19)

For the ﬁfth time, the new theoretical value was in good agreement with the new experimental value.
Brodky and Drell summarized the situation: “Quantum electrodynamics has never been more successful in its confrontation with experiment than it is now. There is really no outstanding discrepancy despite our pursuing the limits of the theory to higher accuracy (...) however, and despite its phenomenal success, the fundamental problems of renormalization in local ﬁeld theory and the nature of the exact solutions of quantum electrodynamics are still to be resolved.” [32]
Starting in the 1970s, all the mathematical calculations necessary to obtain the coeﬃcients of the Dyson series were performed by computer. No source code for these calculations has been published, so it is not possible to reproduce any calculations independently.

9.2 Wesley and Rich, deﬁnitive
The results published by Wesley and Rich were preliminary. In 1971 they published the ﬁnal results of the experiment that turned out to be higher than expected. [35]
The same year, Levine & Wright [37] recalculated the sixth-order factor and obtained a value of +1.49, three times higher that the previous value.

 


g

=

1

+

α 2π

−

0.328

α π

2
+ 1.49

α π

3

g (theor) = 1, 001, 159, 655

g (exp) = 1, 001, 159, 657

(20)

per billion represents ﬁve most accurate comparison between theory and experiment in physics. In spite of the unsatisfactory nature of the renormalization aspects of the theory, there has been no signiﬁcant evidence for a breakdown of QED”. [36]
A few months later, Kinoshita & Cvitanovic [39] published a new calculation for the sixth-order factor, ﬁve times more accurate than Levine & Wright’s previous one. However, this new theoretical value (+1.29) slightly worsened the agreement with the experimental value.



α

α2

α3

 

g = 1 + 2π − 0.328 π + 1.29 π g (theor) = 1, 001, 159, 653
g (exp) = 1, 001, 159, 657

(21)

9.3 Cvitanovic’s conjecture
According to Dyson, the value of the coeﬃcients of the series should grow exponentially, but this did not happen with the coeﬃcients calculated up to that moment. Cvitanovic observed that calculating the coeﬃcients of the Dyson’s series produced many more cancellations than expected. In 1977 he proposed a conjecture [40] according to which the calculation of the coeﬃcients would remain at values close to one. So far, Cvitanovic’s conjecture has not been proven nor has Dyson’s argument been shown to be wrong.
On the other hand, in 1978, the Nobel laureate ’t Hooft presented another argument, completely diﬀerent from Dyson’s argument, but with the same consequences. According to’ t Hooft: “We understand how to renormalize the theory to any ﬁnite order in the perturbation expansion, but it is expected that this expansion will diverge badly, for any value of the coupling constant." [41]

9.4 Landau pole
The Landau pole (or the Moscow zero, or the Landau ghost) is the momentum scale at which the coupling constant of a quantum ﬁeld theory becomes inﬁnite. Such a possibility was pointed out by Landau in 1955. [42]
The asymptotic freedom of QCD was discovered in 1973 by Gross and Wilczek, but asymptotic freedom is not applicable to QED. Landau poles appear in theories that are not asymptotically free, such as QED. In these theories, the renormalized coupling constant grows with energy. In a theory purporting to be complete, this could be considered a mathematical inconsistency.

10 Eight-order Correction (1977-2008)

For the sixth time, the new theoretical value was in good agreement with the new experimental value.
Wesley and Rich summarized the situation: "The agreement between the experimental measurements and QED predictions of the electron g-factor at a level of four parts

10.1 The Penning trap
In 1977, Van Dyck and Dehmelt of the University of Washington used a new technique known as free electron spin resonance. These measurements were based on a device called a Penning trap, which allowed measurements to be obtained

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from individual electrons. These experiments improved the previous results by three orders of magnitude, and, again, the new result excluded previous theoretical value. [43]
To resolve this new discrepancy, the theoretical physicists needed to calculate the the fourth coeﬃcient (eighth-order correction), which involved solving 891 new Feynman diagrams. In 1981, Kinoshita & Lindquist [52] published the ﬁrst calculation of the eight-order coeﬃcient with a value of -0.8.
In 1982, Levine [38] published a new calculation of the sixth-order coeﬃcient with a value of +1.176, lower that the previous one.

 


g

=

1

+

α 2π

−

0.328

α π

2
+ 1.176

α π

3
− 0.8

α π

4

g (theor) = 1.001, 159, 652, 460

g (exp) = 1.001, 159, 652, 410

(22)

For the seventh time, the new theoretical value was in

good agreement with the new experimental value.

10.2 Feynman’s Book
In 1981, Van Dyck and Dehmelt [44] published a second experimental value, lower that the previous one.

 

g (theor) = 1.001, 159, 652, 460

(23)

 g (exp) = 1.001, 159, 652, 222

lation of Drell (+0.15).



α

α2

α3

α4

 

g = 1 + 2π − 0.328 π + 1.181 π g (theor) = 1.001, 159, 652, 201, 2
g (exp) = 1.001, 159, 652, 188, 4

− 1.557 π

(24)

For the eighth time, the new theoretical value was in good

agreement with the new experimental value.

10.4 Muon’s g-factor
QED was also used to calculate the anomalous magnetic moment of the muon. The muon is an unstable subatomic particle with a mean lifetime of 2.2 µs, making high resolution measurements extremely complex. From 1961 to 1976, CERN made the ﬁrst measurements of the muon g-factor. The following experiment was carried out at Brookhaven National Laboratory (BNL). The experiment was named E821 and the results were published from 1997 to 2001. Unfortunately, the theoretical value did not match the new experimental value.
New factors were added to adjust the theoretical ﬁnal result. These new factors came from empirical data obtained from the Standard Model of particle physics. The ﬁrst coeﬃcient was derived from the interaction of the electron with leptons, the second coeﬃcient was derived from the electroweak interaction and the third coeﬃcient was derived from the electron’s interaction with hadrons.

g = g (QED) + g (noQED)

(25)

Just these numbers were used in 1985 by Feynman in his famous book titled "QED: The Strange Theory of Light and Matter". On page 7 of the book, Feynman shows this data and says: "At the present time I can proudly say that there is no signiﬁcant diﬀerence between experiment and theory! (...) To give you a feeling for the accuracy of these numbers, it comes out something like this: If you were to measure the distance from Los Angeles to New York to this accuracy, it would be exact to the thickness of a human hair." [1]
However, at the time of publication of Feynamn’s book there was a real discrepancy between the theoretical and the experimental value that remained for a decade. Van Dyck and Dehmelt [45] published another two new experimental values that increased that discrepancy:
• [1984] : 1.001, 159, 652, 193 [45]
• [1987] : 1.001, 159, 652, 188, 4 [46]
10.3 Analytical sixth-order calculation

g (noQED) = g (µ, τ) + g (weak) + g (hadron) (26)
The inclusion of these new coeﬃcients in the g-factor calculation improved the theoretical muon g-factor value but worsened the theoretical electron g-factor value. This change created a new discrepancy between the theoretical and experimental value of the electron g-factor.
10.5 Harvard experiment
In 2006 a team from Harvard University led by Gabrielse improved the experimental results of Van Dyck and Dehmelt by two orders of magnitude. The Harvard University data were not compatible with previous experimental data provided by the University of Washington. These new data also excluded the theoretical value of the g-factor.
• [2006] : 1.001, 159, 652, 180, 85(76) [48] • [2008] : 1.001, 159, 652, 180, 73(28) [49]

In 1995, Kinoshita’s team published a new value of the eighth-order correction (-1.557), the double of his ﬁrst calculation. [53]. And in 1996, Laporta and Remiddi [47] published the analytical calculation of sixth-order (+1.181). This deﬁnitive value was eight times higher than the initial calcu-

Fig. 5: Harvard vs Washington errors

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Oliver Consa. Something is wrong in the state of QED

October 2021

 


g

=

1

+

α 2π

−

0.328

α π

2
+ 1.181

α π

3

−1.912

α π

4
+ 7.795

α π

5
+ g (noQED)

g (theor) = 1.001, 159, 652, 181, 64

g (exp) = 1.001, 159, 652, 180, 73

(29)

Fig. 6: electron g-factor errors
In 2007, Kinoshita’s team detected an error in his previous calculation of the eighth-order: "Comparing the contributions of individual diagrams of old and new calculations, we found an inconsistency in the old treatment of infrared subtraction terms in two diagrams. Correcting this error leads to the revised value -1.914 for the eight-order term." [54]

For the eleventh time, the new theoretical value was in good agreement with the new experimental value.
In 2017, Laporta [50] published his ﬁnal calculation of the eighth-order coeﬃcient of the Dyson’s series with a value of -1.912, the double of the initial estimation (-0.8). The published value had an unnecessary accuracy of 1100 digits, as a proof that this numerical calculation can be considered the deﬁnitive result.

 


g

=

1

+

α 2π

−

0.328

α π

2

+ 1.181

α π

3

−1.914

α π

4
+ g (noQED)

g (theor) = 1.001, 159, 652, 182.79

g (exp) = 1.001, 159, 652, 180, 73

(27)

For the ninth time, the new theoretical value was in good agreement with the new experimental value.
11 Tenth-order correction (1997-2021)
11.1 Tenth-order correction
Every new calculations of g (noQED) allowed to reduce the discrepancy of the muon g-factor but worsened the discrepancy of the electron g-factor. To resolve this new discrepancy, the theoretical physicists needed to resolve the 12,672 Feynman diagrams of the tenth-order corrections.
In 2012, Kinoshita’s team published the ﬁrst tenth-order coeﬃcient with a value of +9.16, and in the same paper, they published an improved value of -1.909 for the eighth-order contribution. [55]

Fig. 7: First 1100 digits of A8
In 2018, Kinoshita’s team detected an error in his previous calculation of the tenth-order: “we found that one of the integrals, called X024, was given a wrong value in the previous calculation due to an incorrect assignment of integration variables.” [57] The new value was +6.675.



α

α2

α3

 

g = 1 + 2π − 0.328 π + 1.181 π

−1.912

α π

4
+ 6.675

α π

5
+ g (noQED)

g (theor) = 1.001, 159, 652, 182, 032(720)

g (exp) = 1.001, 159, 652, 180, 73(28)

(30)

 


g

=

1

+

α 2π

−

0.328

α π

2
+ 1.181

α π

3

−1.909

α π

4
+ 9.16

α π

5
+ g (noQED)

g (theor) = 1.001, 159, 652, 181, 78

g (exp) = 1.001, 159, 652, 180, 73

(28)

For the tenth time, the new theoretical value was in good agreement with the new experimental value.
In 2015, Kinoshita’s team published an improved value of the tenth-order coeﬃcient with a value of +7.795, and in the same paper, they published an improved value of -1.912 for the eighth-order contribution. [56]

For the twelfth time, the new theoretical value was in good agreement with the new experimental value.

11.2 The muon anomaly
Despite the enormous eﬀort made in recent times, the discrepancy between the theoretical value and the experimental value of the muon g-factor could not be eliminated, maintaining an error greater than 3 sigmas. Theoretical physicists are concerned about this discrepancy, as it is perhaps the most palpable evidence that the Standard Model is incomplete.

 

g (theor) = 1.001, 165, 918.04(51).

(31)

 g (exp) = 1.001, 165, 920.9(6)

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Fig. 8: Muon anomaly
In 2011, the E989 experiment was devised to improve the accuracy of the E821 experiment. This extremely complex experiment was performed at the Fermilab’s Tevatron. Before the experiment could be conducted, a gigantic magnet (15 meters in diameter and 600 tons in weight) had to be moved 1300 km, from BNL to Fermilab. This delicate operation was successfully performed in June 2013. The magnet transfer lasted 35 days and cost 3 million dollars.

ematical inconsistencies and renormalized inﬁnities swept under the rug. We did not expect it to last more than 10 years before some more solidly built theory would replace it. Now, 57 years have gone by and that ramshackle structure still stands.” [71]
All calculations performed in QED always result in an inﬁnite value. Renormalization techniques must be used to obtain ﬁnite results. These Renormalization techniques are not mathematically legitimate. Despite this fact, they have continued to be used because they provide results that ﬁt perfectly with the experimental results. This has provided a kind of "empirical legitimacy" to renormalization.
But for this "empirical legitimacy" to be acceptable, there can be no doubt about the mathematical calculations used. Nevertheless, the lack of critical review of the theoretical results that have been published is evident. The theoretical results are only scrutinized when they do not match the experimental values. It is no longer a surprise that errors continually appear in theoretical calculations. Recall that the calculation of each Feynman diagram implies the resolution of multiple factors, and that each of these factors diverges to inﬁnity. Therefore, renormalization techniques must be arbitrarily applied to eliminate these inﬁnities and to obtain ﬁnite results. Moreover, these calculations are extremely complex and are not published in their entirety, so it is impossible to independently validate them.

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Fig. 9: Transportation of the 600 ton magnet to Fermilab
In addition, the Fermilab particle accelerator had to be enlarged. The related investment plan, the PIP-II Reference Design Report, had an estimated cost of 600 million dollars and was approved in July 2018. The results of E989 experiment were published in 2021, but they conﬁrmed the anomaly once again.
12 Summary
According Feynman: “We have found nothing wrong with the theory of quantum electrodynamics. It is, therefore, I would say, the jewel of physics; our proudest possession.” [1] But the reality of the QED is better reﬂected by Dyson’s description in a letter to Gabrielse in 2006 “As one of the inventors of QED, I remember that we thought of QED in 1949 as a temporary and jerry-built structure, with math-

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