Black hole electron

In physics, there is a speculative notion that if there were a black hole with the same mass, charge and angular momentum as an electron, it would share some of the properties of the electron. Most notably, Brandon Carter showed in 1968 that the magnetic moment of such an object would match that of an electron.^[1] This is interesting because calculations ignoring general relativity and treating the electron as a small rotating sphere of charge give a magnetic moment that is off by roughly a factor of 2, the so-called gyromagnetic ratio.

However, Carter's calculations also show that a would-be black hole with these parameters would be 'super-extremal'. Thus, unlike a true black hole, this object would display a naked singularity, meaning a singularity in spacetime not hidden behind an event horizon. It would also give rise to closed timelike curves.

Standard quantum electrodynamics (QED) treats the electron as a point particle, a view completely supported by experiment. There is no evidence that the electron is a black hole (or naked singularity). Furthermore, since the electron is quantum mechanical in nature, any description purely in terms of general relativity is inadequate.

Details

A paper published in 1938 by Albert Einstein, Leopold Infeld and Banesh Hoffman showed that if elementary particles are treated as singularities in spacetime, it is unnecessary to postulate geodesic motion as part of general relativity.^[2] This makes it somewhat interesting to explore the idea of treating the electron as such a singularity.

If we ignore the electron's angular momentum and charge, as well as the effects of quantum mechanics, we can treat the electron as a black hole and attempt to compute its radius. The Schwarzschild radius $r s$ of a mass $m$ is the radius of the event horizon for an non-rotating, uncharged black hole of that mass. It is given by

r_{s}={\frac {2Gm}{c^{2}}}

where $G$ is Newton's gravitational constant and $c$ is the speed of light. For the electron,

m

= 9.109×10⁻³¹ kg,

r s

= 1.353×10⁻⁵⁷ m.

Thus, if we ignore the electric charge and angular momentum of the electron, and naively apply general relativity on this very small length scale without taking quantum theory into account, a black hole of the electron's mass would have this radius.

In reality, physicists expect quantum gravity effects to become significant even at much larger length scales, comparable to the Planck length

\ell _{P}={\sqrt {\frac {G\hbar }{c^{3}}}}=1.616\times 10^{-35}

So, the above purely classical calculation cannot be trusted. Furthermore, even classically, electric charge and angular momentum affect the properties of a black hole. To take them into account, while still ignoring quantum effects, we should use the Kerr-Newman metric. If we do, we find the angular momentum and charge of the electron are too large for a black hole of the electron's mass: a Kerr-Newman object with such a large angular momentum and charge would instead be 'super-extremal', displaying a naked singularity, meaning a singularity not shielded by an event horizon.

To see that this is so, it suffices to consider the electron's charge and neglect its angular momentum. In the Reissner–Nordström metric, which describes electrically charged but non-rotating black holes, there is a quantity $r q$ , defined by

r_{{q}}={\sqrt {{\frac {q^{{2}}G}{4\pi \epsilon _{{0}}c^{{4}}}}}}

where $q$ is the electron's charge and $ε 0$ is the vacuum permittivity. For an electron with $q$ = − $e$ = 3018839800000000000♠−1.602×10⁻¹⁹ C, this gives a value

r q

= 1.3807×10⁻³⁶ m.

Since this (vastly) exceeds the Schwarzschild radius, the Reissner–Nordström metric has a naked singularity.

If we include the effects of the electron's rotation using the Kerr-Newman metric, there is still a naked singularity, which is now a ring singularity, and spacetime also has closed timelike curves. The size of this ring singularity is on the order of

r_{a}={\frac {J}{mc}}

where as before $m$ is the electron's mass and $c$ is the speed of light, but $J$ = $\hbar /2$ is the spin angular momentum of the electron. This gives

r a

= 1.9295×10⁻¹³ m

which is much larger than the length scale $r q$ associated to the electron's charge. As noted by Carter,^[3] this length $r a$ is on the order of the electron's Compton wavelength. Unlike the Compton wavelength, it is not quantum mechanical in nature.

More recently, Alexander Burinskii has pursued the idea of treating the electron as Kerr-Newman naked singularity .^[4]^[5]

References

↑ Carter, B. (25 October 1968). "Global structure of the Kerr family of gravitational fields". Physical Review. 174 (5): 1559–1571.
↑ Einstein, A.; Infeld, L.; Hoffmann, B. (January 1938). "The gravitational equations and the problem of motion". Annals of Mathematics. Second Series. 39 (1): 65–100. doi:10.2307/1968714. JSTOR 1968714.
↑ Carter, B. (25 October 1968). "Global structure of the Kerr family of gravitational fields". Physical Review. 174 (5): 1559–1571.
↑ Burinskii, Alexander (April 2008). "The Dirac-Kerr-Newman electron". Gravitation and Cosmology. 14 (2): 109–122. arXiv:hep-th/0507109. Bibcode:2008GrCo...14..109B. doi:10.1134/S0202289308020011.
↑ Burinskii, Alexander (2007). "Kerr geometry as space–time structure of the Dirac electron". arXiv:0712.0577.

Duff, Michael (1994). "Kaluza–Klein theory in perspective". arXiv:hep-th/9410046.
Hawking, Stephen (1971). "Gravitationally collapsed objects of very low mass". Monthly Notices of the Royal Astronomical Society. 152: 75. Bibcode:1971MNRAS.152...75H. doi:10.1093/mnras/152.1.75.
Penrose, Roger (2004). The Road to Reality: A Complete Guide to the Laws of the Universe. London: Jonathan Cape.
Salam, Abdus. "Impact of quantum gravity theory on particle physics". In Isham, C. J.; Penrose, Roger; Sciama, Dennis William. Quantum Gravity: an Oxford Symposium. Oxford University Press.
't Hooft, Gerard (1990). "The black hole interpretation of string theory". Nuclear Physics B. 335: 138–154. Bibcode:1990NuPhB.335..138T. doi:10.1016/0550-3213(90)90174-C.

Popular literature

Brian Greene, The Elegant Universe: Superstrings, Hidden Dimensions, and the Quest for the Ultimate Theory (1999), (See chapter 13)
John A. Wheeler, Geons, Black Holes & Quantum Foam (1998), (See chapter 10)

Black holes

Types	Schwarzschild Rotating Charged Virtual Binary

Size	Micro Extremal Electron Stellar Intermediate-mass Supermassive Quasar Active galactic nucleus Blazar Large quasar group

Formation	Stellar evolution Gravitational collapse Neutron star Related links Compact star Quark Exotic Tolman–Oppenheimer–Volkoff limit White dwarf Related links Supernova Related links Hypernova Gamma-ray burst

Properties	Thermodynamics Schwarzschild radius M–sigma relation Event horizon Quasi-periodic oscillation Photon sphere Ergosphere Hawking radiation Penrose process Blandford–Znajek process Bondi accretion Spaghettification Gravitational lens

Models	Gravitational singularity Penrose–Hawking singularity theorems Primordial black hole Gravastar Dark star Dark-energy star Black star Eternally collapsing object Magnetospheric eternally collapsing object Fuzzball White hole Naked singularity Ring singularity Immirzi parameter Membrane paradigm Kugelblitz Wormhole Quasi-star

Issues	No-hair theorem Information paradox Cosmic censorship Alternative models Holographic principle Black hole complementarity firewall (physics) ER=EPR Final parsec problem

Metrics	Schwarzschild Kerr Reissner–Nordström Kerr–Newman

Lists	Black holes Most massive Quasars

Related	Timeline of black hole physics Rossi X-ray Timing Explorer Hypercompact stellar system Black hole starship

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Black hole electron

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References

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Popular literature