Fine-structure constant

Some equivalent definitions of α in terms of other fundamental physical constants are:

${\displaystyle \alpha ={\frac {1}{4\pi \varepsilon _{0}}}{\frac {e^{2}}{\hbar c}}={\frac {\mu _{0}}{4\pi }}{\frac {e^{2}c}{\hbar }}={\frac {k_{\text{e}}e^{2}}{\hbar c}}={\frac {e^{2}}{2\varepsilon _{0}ch}}={\frac {c\mu _{0}}{2R_{\text{K}}}}={\frac {e^{2}Z_{0}}{2h}}={\frac {e^{2}Z_{0}}{4\pi \hbar }}}$

where:

• e is the elementary charge (:= 1.602176634×10⁻¹⁹ C);
• π is the mathematical constant pi;
• h is the Planck constant (:= 6.62607015×10⁻³⁴ J⋅s);
• ħ = h/2π is the reduced Planck constant (:= 6.62607015×10⁻³⁴ J⋅s/2π);
• c is the speed of light in vacuum (= 299792458 m/s);
• ε₀ is the electric constant or permittivity in vacuum (or free space);
• µ₀ is the magnetic constant or permeability in vacuum (or free space)
• k_e is the Coulomb constant;
• R_K is the von Klitzing constant;
• Z₀ is the vacuum impedance or impedance in free space.

When the other constants (c, h and e) have defined values, the definition reflects the relationship between α and the permeability of free space µ₀, which equals µ₀ = 2hα/ce². In the 2019 redefinition of SI base units, 4π × 1.00000000082(20)×10⁻⁷ H⋅m⁻¹ is the value for µ₀ based upon more accurate measurements of the fine structure constant.[3][4][5]

Two example eighth-order Feynman diagrams that contribute to the electron self-interaction. The horizontal line with an arrow represents the electron while the wavy lines are virtual photons, and the circles represent virtual electron–positron pairs.

The 2018 CODATA recommended value of α is[7]

α = e²/4πε₀ħc = 0.0072973525693(11).

This has a relative standard uncertainty of 0.15 parts per billion.[7]

This value for α gives µ₀ = 4π × 1.00000000054(15)×10⁻⁷ H⋅m⁻¹, 3.6 standard deviations away from its old defined value, but with the mean differing from the old value by only 0.54 parts per billion.

For reasons of convenience, historically the value of the reciprocal of the fine-structure constant is often specified. The 2018 CODATA recommended value is given by[1]

α⁻¹ = 137.035999084(21).

While the value of α can be estimated from the values of the constants appearing in any of its definitions, the theory of quantum electrodynamics (QED) provides a way to measure α directly using the quantum Hall effect or the anomalous magnetic moment of the electron. Other methods include the AC Josephson effect and photon recoil in atom interferometry.[8] There is general agreement for the value of α, as measured by these different methods. The preferred methods in 2019 are measurements of electron anomalous magnetic moments and of photon recoil in atom interferometry.[8] The theory of QED predicts a relationship between the dimensionless magnetic moment of the electron and the fine-structure constant α (the magnetic moment of the electron is also referred to as "Landé g-factor" and symbolized as g). The most precise value of α obtained experimentally (as of 2012) is based on a measurement of g using a one-electron so-called "quantum cyclotron" apparatus, together with a calculation via the theory of QED that involved 12672 tenth-order Feynman diagrams:[9]

α⁻¹ = 137.035999174(35).

This measurement of α has a relative standard uncertainty of 2.5×10⁻¹⁰. This value and uncertainty are about the same as the latest experimental results.[10]

The fine-structure constant, α, has several physical interpretations. α is:

• The ratio of two energies: (i) the energy needed to overcome the electrostatic repulsion between two electrons a distance of d apart, and (ii) the energy of a single photon of wavelength λ = 2πd (or of angular wavelength d; see Planck relation):

${\displaystyle \alpha =\left.{\frac {e^{2}}{4\pi \varepsilon _{0}d}}\right/{\frac {hc}{\lambda }}={\frac {e^{2}}{4\pi \varepsilon _{0}d}}\times {\frac {2\pi d}{hc}}={\frac {e^{2}}{4\pi \varepsilon _{0}d}}\times {\frac {d}{\hbar c}}={\frac {e^{2}}{4\pi \varepsilon _{0}\hbar c}}.}$

• The ratio of the velocity of the electron in the first circular orbit of the Bohr model of the atom, which is 1/4πε₀ e²/ħ, to the speed of light in vacuum, c.[11] This is Sommerfeld's original physical interpretation. Then the square of α is the ratio between the Hartree energy (27.2 eV = twice the Rydberg energy = approximately twice its ionization energy) and the electron rest energy (511 keV).
• The two ratios of three characteristic lengths: the classical electron radius r_e, the Compton wavelength of the electron λ_e, and the Bohr radius a₀:

${\displaystyle r_{\text{e}}={\frac {\alpha \lambda _{\text{e}}}{2\pi }}=\alpha ^{2}a_{0}}$

• In quantum electrodynamics, α is directly related to the coupling constant determining the strength of the interaction between electrons and photons.[12] The theory does not predict its value. Therefore, α must be determined experimentally. In fact, α is one of about 20 empirical parameters in the Standard Model of particle physics, whose value is not determined within the Standard Model.
• In the electroweak theory unifying the weak interaction with electromagnetism, α is absorbed into two other coupling constants associated with the electroweak gauge fields. In this theory, the electromagnetic interaction is treated as a mixture of interactions associated with the electroweak fields. The strength of the electromagnetic interaction varies with the strength of the energy field.
• In the fields of electrical engineering and solid-state physics, the fine-structure constant is one fourth the product of the characteristic impedance of free space, Z₀ = μ₀c, and the conductance quantum, G₀ = 2e²/h:

${\displaystyle \alpha ={\tfrac {1}{4}}Z_{0}G_{0}}$.

The optical conductivity of graphene for visible frequencies is theoretically given by πG₀/4, and as a result its light absorption and transmission properties can be expressed in terms of the fine structure constant alone.[13] The absorption value for normal-incident light on graphene in vacuum would then be given by πα/(1 + πα/2)² or 2.24%, and the transmission by 1/(1 + πα/2)² or 97.75% (experimentally observed to be between 97.6% and 97.8%).

• The fine-structure constant gives the maximum positive charge of an atomic nucleus that will allow a stable electron-orbit around it within the Bohr model (element feynmanium).[14] For an electron orbiting an atomic nucleus with atomic number Z, mv²/r = 1/4πε₀ Ze²/r². The Heisenberg uncertainty principle momentum/position uncertainty relationship of such an electron is just mvr = ħ. The relativistic limiting value for v is c, and so the limiting value for Z is the reciprocal of the fine-structure constant, 137.[15]
• The magnetic moment of the electron indicates that the charge is circulating at a radius r_Q with the velocity of light.[16] It generates the radiation energy m_ec² and has an angular momentum L = 1 ħ = r_Qm_ec. The field energy of the stationary Coulomb field is m_ec² = e²/4πε₀r_e and defines the classical electron radius r_e. These values inserted into the definition of alpha yields α = r_e/r_Q. It compares the dynamic structure of the electron with the classical static assumption.
• Alpha is related to the probability that an electron will emit or absorb a photon.[17]
• Given two hypothetical point particles each of Planck mass and elementary charge, separated by any distance, α is the ratio of their electrostatic repulsive force to their gravitational attractive force.
• The square of the ratio of the elementary charge to the Planck charge

${\displaystyle \alpha =\left({\frac {e}{q_{\text{P}}}}\right)^{2}.}$

When perturbation theory is applied to quantum electrodynamics, the resulting perturbative expansions for physical results are expressed as sets of power series in α. Because α is much less than one, higher powers of α are soon unimportant, making the perturbation theory practical in this case. On the other hand, the large value of the corresponding factors in quantum chromodynamics makes calculations involving the strong nuclear force extremely difficult.

In quantum electrodynamics, the more thorough quantum field theory underlying the electromagnetic coupling, the renormalization group dictates how the strength of the electromagnetic interaction grows logarithmically as the relevant energy scale increases. The value of the fine-structure constant α is linked to the observed value of this coupling associated with the energy scale of the electron mass: the electron is a lower bound for this energy scale, because it (and the positron) is the lightest charged object whose quantum loops can contribute to the running. Therefore, 1/137.036 is the asymptotic value of the fine-structure constant at zero energy. At higher energies, such as the scale of the Z boson, about 90 GeV, one measures an effective α ≈ 1/127, instead.

As the energy scale increases, the strength of the electromagnetic interaction in the Standard Model approaches that of the other two fundamental interactions, a feature important for grand unification theories. If quantum electrodynamics were an exact theory, the fine-structure constant would actually diverge at an energy known as the Landau pole—this fact undermines the consistency of quantum electrodynamics beyond perturbative expansions.

Sommerfeld memorial at University of Munich

Based on the precise measurement of the hydrogen atom spectrum by Michelson and Morley in 1887,[18] Arnold Sommerfeld extended the Bohr model to include elliptical orbits and relativistic dependence of mass on velocity. He introduced a term for the fine-structure constant in 1916.[19] The first physical interpretation of the fine-structure constant α was as the ratio of the velocity of the electron in the first circular orbit of the relativistic Bohr atom to the speed of light in the vacuum.[20] Equivalently, it was the quotient between the minimum angular momentum allowed by relativity for a closed orbit, and the minimum angular momentum allowed for it by quantum mechanics. It appears naturally in Sommerfeld's analysis, and determines the size of the splitting or fine-structure of the hydrogenic spectral lines. This constant was not seen as significant until Paul Dirac's linear relativistic wave equation in 1928, which gave the exact fine structure formula.[21]^:407

With the development of quantum electrodynamics (QED) the significance of α has broadened from a spectroscopic phenomenon to a general coupling constant for the electromagnetic field, determining the strength of the interaction between electrons and photons. The term α/2π is engraved on the tombstone of one of the pioneers of QED, Julian Schwinger, referring to his calculation of the anomalous magnetic dipole moment.

Physicists have pondered whether the fine-structure constant is in fact constant, or whether its value differs by location and over time. A varying α has been proposed as a way of solving problems in cosmology and astrophysics.[22][23][24][25] String theory and other proposals for going beyond the Standard Model of particle physics have led to theoretical interest in whether the accepted physical constants (not just α) actually vary.

In the experiments below, Δα represents the change in α over time, which can be computed by α_prev − α_now. If the fine-structure constant really is a constant, then any experiment should show that

${\displaystyle {\frac {\Delta \alpha }{\alpha }}\ {\stackrel {\mathrm {def} }{=}}\ {\frac {\alpha _{\mathrm {prev} }-\alpha _{\mathrm {now} }}{\alpha _{\mathrm {now} }}}=0,}$

or as close to zero as experiment can measure. Any value far away from zero would indicate that α does change over time. So far, most experimental data is consistent with α being constant.

The anthropic principle is a controversial argument of why the fine-structure constant has the value it does: stable matter, and therefore life and intelligent beings, could not exist if its value were much different. For instance, were α to change by 4%, stellar fusion would not produce carbon, so that carbon-based life would be impossible. If α were greater than 0.1, stellar fusion would be impossible, and no place in the universe would be warm enough for life as we know it.[55]

As a dimensionless constant which does not seem to be directly related to any mathematical constant, the fine-structure constant has long fascinated physicists.

Arthur Eddington argued that the value could be "obtained by pure deduction" and he related it to the Eddington number, his estimate of the number of protons in the universe.[56] This led him in 1929 to conjecture that the reciprocal of the fine-structure constant was not approximately the integer 137, but precisely the integer 137.[57] Other physicists neither adopted this conjecture nor accepted his arguments but by the 1940s experimental values for 1/α deviated sufficiently from 137 to refute Eddington's argument.[21]

The fine-structure constant so intrigued physicist Wolfgang Pauli that he collaborated with psychoanalyst Carl Jung in a quest to understand its significance.[58] Similarly, Max Born believed that would the value of alpha differ, the universe would degenerate. Thus, he asserted that 1/137 is a law of nature.[59]

Richard Feynman, one of the originators and early developers of the theory of quantum electrodynamics (QED), referred to the fine-structure constant in these terms:

There is a most profound and beautiful question associated with the observed coupling constant, e – the amplitude for a real electron to emit or absorb a real photon. It is a simple number that has been experimentally determined to be close to 0.08542455. (My physicist friends won't recognize this number, because they like to remember it as the inverse of its square: about 137.03597 with about an uncertainty of about 2 in the last decimal place. It has been a mystery ever since it was discovered more than fifty years ago, and all good theoretical physicists put this number up on their wall and worry about it.) Immediately you would like to know where this number for a coupling comes from: is it related to pi or perhaps to the base of natural logarithms? Nobody knows. It's one of the greatest damn mysteries of physics: a magic number that comes to us with no understanding by man. You might say the "hand of God" wrote that number, and "we don't know how He pushed his pencil." We know what kind of a dance to do experimentally to measure this number very accurately, but we don't know what kind of dance to do on the computer to make this number come out, without putting it in secretly!

— Richard P. Feynman (1985). QED: The Strange Theory of Light and Matter. Princeton University Press. p. 129. ISBN 978-0-691-08388-9.

Conversely, statistician I. J. Good argued that a numerological explanation would only be acceptable if it could be based on a good theory that is not yet known but "exists" in the sense of a Platonic Ideal.[60]

Attempts to find a mathematical basis for this dimensionless constant have continued up to the present time. However, no numerological explanation has ever been accepted by the physics community.

In the early 21st century, multiple physicists, including Stephen Hawking in his book A Brief History of Time, began exploring the idea of a multiverse, and the fine-structure constant was one of several universal constants that suggested the idea of a fine-tuned universe.[61]

The mystery about α is actually a double mystery. The first mystery – the origin of its numerical value α ≈ 1/137 – has been recognized and discussed for decades. The second mystery – the range of its domain – is generally unrecognized.

— M. H. MacGregor (2007). The Power of Alpha. World Scientific. p. 69. ISBN 978-981-256-961-5.

• Dimensionless physical constant
• Electric constant
• Gravitational coupling constant
• Hyperfine structure
• Planck's constant
• Speed of light

Wikiquote has quotations related to: Fine-structure constant

• Stephen L. Adler, "Theories of the Fine Structure Constant α" FERMILAB-PUB-72/059-T
• "Introduction to the constants for nonexperts", adapted from the Encyclopædia Britannica, 15th ed. Disseminated by the NIST web page.
• CODATA recommended value of α, as of 2010.
• Quotes About Fine Structure Constant
• "Fine Structure Constant", Eric Weisstein's World of Physics website.
• John D. Barrow, and John K. Webb, "Inconstant Constants", Scientific American, June 2005.
• Eaves, Laurence (2009). "The Fine Structure Constant". Sixty Symbols. Brady Haran for the University of Nottingham.