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Schwinger effect

April 15, 2024

The Schwinger effect is a predicted physical phenomenon whereby matter is created by a strong electric field. It is also referred to as the Sauter–Schwinger effect, Schwinger mechanism, or Schwinger pair production. It is a prediction of quantum electrodynamics (QED) in which electronpositron pairs are spontaneously created in the presence of an electric field, thereby causing the decay of the electric field. The effect was originally proposed by Fritz Sauter in 1931[1] and further important work was carried out by Werner Heisenberg and Hans Heinrich Euler in 1936,[2] though it was not until 1951 that Julian Schwinger gave a complete theoretical description.[3]

In the presence of a strong, constant electric field, electrons, e, and positrons, e+, will be spontaneously created.

The Schwinger effect can be thought of as vacuum decay in the presence of an electric field. Although the notion of vacuum decay suggests that something is created out of nothing, physical conservation laws are nevertheless obeyed. To understand this, note that electrons and positrons are each other's antiparticles, with identical properties except opposite electric charge.

To conserve energy, the electric field loses energy when an electron–positron pair is created, by an amount equal to , where is the electron rest mass and is the speed of light. Electric charge is conserved because an electron–positron pair is charge neutral. Linear and angular momentum are conserved because, in each pair, the electron and positron are created with opposite velocities and spins. In fact, the electron and positron are expected to be created at (close to) rest, and then subsequently accelerated away from each other by the electric field.[4]

Mathematical description edit

Schwinger pair production in a constant electric field takes place at a constant rate per unit volume, commonly referred to as  . The rate was first calculated by Schwinger[3] and at leading (one-loop) order is equal to

 

where   is the mass of an electron,   is the elementary charge, and   is the electric field strength. This formula cannot be expanded in a Taylor series in  , showing the nonperturbative nature of this effect. In terms of Feynman diagrams, one can derive the rate of Schwinger pair production by summing the infinite set of diagrams shown below, containing one electron loop and any number of external photon legs, each with zero energy.

 
The infinite set of Feynman diagrams relevant for Schwinger pair production.

Experimental prospects edit

The original Schwinger effect of quantum electrodynamics has never been observed due to the extremely strong electric-field strengths required. Pair production takes place exponentially slowly when the electric field strength is much below the Schwinger limit, corresponding to approximately 1018 V/m. With current and planned laser facilities, this is an unfeasibly strong electric-field strength, so various mechanisms have been proposed to speed up the process and thereby reduce the electric-field strength required for its observation.

The rate of pair production may be significantly increased in time-dependent electric fields,[5][6][7] and as such is being pursued by high-intensity laser experiments such as the Extreme Light Infrastructure.[8] Another possibility is to include a highly charged nucleus which itself produces a strong electric field.[9]

By electromagnetic duality, the same mechanism in a magnetic field should produce magnetic monopoles, if they exist. A search conducted using the Large Hadron Collider failed to detect monopoles, and analysis indicated a lower bound on monopole mass of 75 GeV/c2 at the 95% confidence level.[10]

In January 2022, researchers at the National Graphene Institute led by Andre Geim and a number of other collaborators reported the observation of an analog process between electrons and holes at the Dirac point of a superlattice of graphene on hexagonal boron nitride (G/hBN) and another one of twisted bilayer graphene (TBG). An interpretation as Zener–Klein tunneling (a mix[11] between Zener tunneling and Klein tunneling) is also utilized.[12][13][14] In June 2023, researchers at the  Ecole Normale Supérieure in Paris and their collaborators reported the quantitative measurement of the Schwinger-pair production rate in doped graphene transistors in a 1D geometry. [15]

See also edit

References edit

  1. ^ Sauter, Fritz (1931). "Über das Verhalten eines Elektrons im homogenen elektrischen Feld nach der relativistischen Theorie Diracs". Zeitschrift für Physik (in German). 69 (11–12). Springer Science and Business Media LLC: 742–764. Bibcode:1931ZPhy...69..742S. doi:10.1007/bf01339461. ISSN 1434-6001. S2CID 122120733.
  2. ^ Heisenberg, W.; Euler, H. (1936). "Folgerungen aus der Diracschen Theorie des Positrons". Zeitschrift für Physik (in German). 98 (11–12): 714–732. arXiv:physics/0605038. Bibcode:1936ZPhy...98..714H. doi:10.1007/bf01343663. ISSN 1434-6001.
  3. ^ a b Schwinger, Julian (1951-06-01). "On Gauge Invariance and Vacuum Polarization". Physical Review. 82 (5). American Physical Society (APS): 664–679. Bibcode:1951PhRv...82..664S. doi:10.1103/physrev.82.664. ISSN 0031-899X.
  4. ^ A.I. Nikishov (1970). "Pair Production by a Constant External Field". Journal of Experimental and Theoretical Physics. 30: 660.
  5. ^ Brezin, E.; Itzykson, C. (1970-10-01). "Pair Production in Vacuum by an Alternating Field". Physical Review D. 2 (7). American Physical Society (APS): 1191–1199. Bibcode:1970PhRvD...2.1191B. doi:10.1103/physrevd.2.1191. ISSN 0556-2821.
  6. ^ Ringwald, A. (2001). "Pair production from vacuum at the focus of an X-ray free electron laser". Physics Letters B. 510 (1–4): 107–116. arXiv:hep-ph/0103185. Bibcode:2001PhLB..510..107R. doi:10.1016/s0370-2693(01)00496-8. ISSN 0370-2693. S2CID 14417813.
  7. ^ Popov, V. S. (2001). "Schwinger mechanism of electron–positron pair production by the field of optical and X-ray lasers in vacuum". Journal of Experimental and Theoretical Physics Letters. 74 (3). Pleiades Publishing Ltd: 133–138. Bibcode:2001JETPL..74..133P. doi:10.1134/1.1410216. ISSN 0021-3640. S2CID 121532558.
  8. ^ I. C. E. Turcu; et al. (2016). (PDF). Romanian Reports in Physics. 68: S145-S231. Archived from the original (PDF) on 2022-07-07. Retrieved 2020-01-11.
  9. ^ Müller, C.; Voitkiv, A. B.; Grün, N. (2003-06-24). "Differential rates for multiphoton pair production by an ultrarelativistic nucleus colliding with an intense laser beam". Physical Review A. 67 (6). American Physical Society (APS): 063407. Bibcode:2003PhRvA..67f3407M. doi:10.1103/physreva.67.063407. ISSN 1050-2947.
  10. ^ Acharya, B.; Alexandre, J.; Benes, P.; Bergmann, B.; Bertolucci, S.; et al. (2022-02-02). "Search for magnetic monopoles produced via the Schwinger mechanism". Nature. 602 (7895). Springer Science and Business Media LLC: 63–67. Bibcode:2022Natur.602...63A. doi:10.1038/s41586-021-04298-1. hdl:11585/852746. ISSN 0028-0836. PMID 35110756. S2CID 246488582.
  11. ^ Vandecasteele, Niels; Barreiro, Amelia; Lazzeri, Michele; Bachtold, Adrian; Mauri, Francesco (2010-07-20). "Current-voltage characteristics of graphene devices: Interplay between Zener–Klein tunneling and defects". Physical Review B. 82 (4): 045416. arXiv:1003.2072. Bibcode:2010PhRvB..82d5416V. doi:10.1103/PhysRevB.82.045416. hdl:10261/44538. ISSN 1098-0121. S2CID 38911270.
  12. ^ Berdyugin, Alexey I.; Xin, Na; Gao, Haoyang; Slizovskiy, Sergey; Dong, Zhiyu; Bhattacharjee, Shubhadeep; Kumaravadivel, P.; Xu, Shuigang; Ponomarenko, L. A.; Holwill, Matthew; Bandurin, D. A. (2022-01-28). "Out-of-equilibrium criticalities in graphene superlattices". Science. 375 (6579): 430–433. arXiv:2106.12609. Bibcode:2022Sci...375..430B. doi:10.1126/science.abi8627. ISSN 0036-8075. PMID 35084955. S2CID 235623859.
  13. ^ "Schwinger effect seen in graphene". Physics World. 2022-03-25. Retrieved 2022-03-28.
  14. ^ "Physicists Prove You Can Make Something out of Nothing by Simulating Cosmic Physics". The Debrief. 2022-09-19. Retrieved 2023-02-27.
  15. ^ Schmitt, A.; Vallet, P.; Mele, D.; Rosticher, M.; Taniguchi, T.; Watanabe, K.; Bocquillon, E.; Fève, G.; Berroir, J. M.; Voisin, C.; Cayssol, J.; Goerbig, M. O.; Troost, J.; Baudin, E.; Plaçais, B. (2023-06-15). "Mesoscopic Klein-Schwinger effect in graphene". Nature Physics. 19 (6): 830–835. arXiv:2207.13400. Bibcode:2023NatPh..19..830S. doi:10.1038/s41567-023-01978-9. ISSN 1745-2473. S2CID 251105038.

April 15, 2024
schwinger, effect, predicted, physical, phenomenon, whereby, matter, created, strong, electric, field, also, referred, sauter, schwinger, mechanism, schwinger, pair, production, prediction, quantum, electrodynamics, which, electron, positron, pairs, spontaneou. The Schwinger effect is a predicted physical phenomenon whereby matter is created by a strong electric field It is also referred to as the Sauter Schwinger effect Schwinger mechanism or Schwinger pair production It is a prediction of quantum electrodynamics QED in which electron positron pairs are spontaneously created in the presence of an electric field thereby causing the decay of the electric field The effect was originally proposed by Fritz Sauter in 1931 1 and further important work was carried out by Werner Heisenberg and Hans Heinrich Euler in 1936 2 though it was not until 1951 that Julian Schwinger gave a complete theoretical description 3 In the presence of a strong constant electric field electrons e and positrons e will be spontaneously created The Schwinger effect can be thought of as vacuum decay in the presence of an electric field Although the notion of vacuum decay suggests that something is created out of nothing physical conservation laws are nevertheless obeyed To understand this note that electrons and positrons are each other s antiparticles with identical properties except opposite electric charge To conserve energy the electric field loses energy when an electron positron pair is created by an amount equal to 2mec2 displaystyle 2m text e c 2 where me displaystyle m text e is the electron rest mass and c displaystyle c is the speed of light Electric charge is conserved because an electron positron pair is charge neutral Linear and angular momentum are conserved because in each pair the electron and positron are created with opposite velocities and spins In fact the electron and positron are expected to be created at close to rest and then subsequently accelerated away from each other by the electric field 4 Contents 1 Mathematical description 2 Experimental prospects 3 See also 4 ReferencesMathematical description editSchwinger pair production in a constant electric field takes place at a constant rate per unit volume commonly referred to as G displaystyle Gamma nbsp The rate was first calculated by Schwinger 3 and at leading one loop order is equal to G eE 24p3ℏ2c n 1 1n2exp pm2c3nℏeE displaystyle Gamma frac eE 2 4 pi 3 hbar 2 c sum n 1 infty frac 1 n 2 exp left frac pi m 2 c 3 n hbar eE right nbsp where m displaystyle m nbsp is the mass of an electron e displaystyle e nbsp is the elementary charge and E displaystyle E nbsp is the electric field strength This formula cannot be expanded in a Taylor series in e2 displaystyle e 2 nbsp showing the nonperturbative nature of this effect In terms of Feynman diagrams one can derive the rate of Schwinger pair production by summing the infinite set of diagrams shown below containing one electron loop and any number of external photon legs each with zero energy nbsp The infinite set of Feynman diagrams relevant for Schwinger pair production Experimental prospects editThe original Schwinger effect of quantum electrodynamics has never been observed due to the extremely strong electric field strengths required Pair production takes place exponentially slowly when the electric field strength is much below the Schwinger limit corresponding to approximately 1018 V m With current and planned laser facilities this is an unfeasibly strong electric field strength so various mechanisms have been proposed to speed up the process and thereby reduce the electric field strength required for its observation The rate of pair production may be significantly increased in time dependent electric fields 5 6 7 and as such is being pursued by high intensity laser experiments such as the Extreme Light Infrastructure 8 Another possibility is to include a highly charged nucleus which itself produces a strong electric field 9 By electromagnetic duality the same mechanism in a magnetic field should produce magnetic monopoles if they exist A search conducted using the Large Hadron Collider failed to detect monopoles and analysis indicated a lower bound on monopole mass of 75 GeV c2 at the 95 confidence level 10 In January 2022 researchers at the National Graphene Institute led by Andre Geim and a number of other collaborators reported the observation of an analog process between electrons and holes at the Dirac point of a superlattice of graphene on hexagonal boron nitride G hBN and another one of twisted bilayer graphene TBG An interpretation as Zener Klein tunneling a mix 11 between Zener tunneling and Klein tunneling is also utilized 12 13 14 In June 2023 researchers at the Ecole Normale Superieure in Paris and their collaborators reported the quantitative measurement of the Schwinger pair production rate in doped graphene transistors in a 1D geometry 15 See also editSchwinger limit Vacuum polarization Uehling potential Euler Heisenberg Lagrangian MoEDAL experimentReferences edit Sauter Fritz 1931 Uber das Verhalten eines Elektrons im homogenen elektrischen Feld nach der relativistischen Theorie Diracs Zeitschrift fur Physik in German 69 11 12 Springer Science and Business Media LLC 742 764 Bibcode 1931ZPhy 69 742S doi 10 1007 bf01339461 ISSN 1434 6001 S2CID 122120733 Heisenberg W Euler H 1936 Folgerungen aus der Diracschen Theorie des Positrons Zeitschrift fur Physik in German 98 11 12 714 732 arXiv physics 0605038 Bibcode 1936ZPhy 98 714H doi 10 1007 bf01343663 ISSN 1434 6001 a b Schwinger Julian 1951 06 01 On Gauge Invariance and Vacuum Polarization Physical Review 82 5 American Physical Society APS 664 679 Bibcode 1951PhRv 82 664S doi 10 1103 physrev 82 664 ISSN 0031 899X A I Nikishov 1970 Pair Production by a Constant External Field Journal of Experimental and Theoretical Physics 30 660 Brezin E Itzykson C 1970 10 01 Pair Production in Vacuum by an Alternating Field Physical Review D 2 7 American Physical Society APS 1191 1199 Bibcode 1970PhRvD 2 1191B doi 10 1103 physrevd 2 1191 ISSN 0556 2821 Ringwald A 2001 Pair production from vacuum at the focus of an X ray free electron laser Physics Letters B 510 1 4 107 116 arXiv hep ph 0103185 Bibcode 2001PhLB 510 107R doi 10 1016 s0370 2693 01 00496 8 ISSN 0370 2693 S2CID 14417813 Popov V S 2001 Schwinger mechanism of electron positron pair production by the field of optical and X ray lasers in vacuum Journal of Experimental and Theoretical Physics Letters 74 3 Pleiades Publishing Ltd 133 138 Bibcode 2001JETPL 74 133P doi 10 1134 1 1410216 ISSN 0021 3640 S2CID 121532558 I C E Turcu et al 2016 High field physics and QED experiments at ELI NP PDF Romanian Reports in Physics 68 S145 S231 Archived from the original PDF on 2022 07 07 Retrieved 2020 01 11 Muller C Voitkiv A B Grun N 2003 06 24 Differential rates for multiphoton pair production by an ultrarelativistic nucleus colliding with an intense laser beam Physical Review A 67 6 American Physical Society APS 063407 Bibcode 2003PhRvA 67f3407M doi 10 1103 physreva 67 063407 ISSN 1050 2947 Acharya B Alexandre J Benes P Bergmann B Bertolucci S et al 2022 02 02 Search for magnetic monopoles produced via the Schwinger mechanism Nature 602 7895 Springer Science and Business Media LLC 63 67 Bibcode 2022Natur 602 63A doi 10 1038 s41586 021 04298 1 hdl 11585 852746 ISSN 0028 0836 PMID 35110756 S2CID 246488582 Vandecasteele Niels Barreiro Amelia Lazzeri Michele Bachtold Adrian Mauri Francesco 2010 07 20 Current voltage characteristics of graphene devices Interplay between Zener Klein tunneling and defects Physical Review B 82 4 045416 arXiv 1003 2072 Bibcode 2010PhRvB 82d5416V doi 10 1103 PhysRevB 82 045416 hdl 10261 44538 ISSN 1098 0121 S2CID 38911270 Berdyugin Alexey I Xin Na Gao Haoyang Slizovskiy Sergey Dong Zhiyu Bhattacharjee Shubhadeep Kumaravadivel P Xu Shuigang Ponomarenko L A Holwill Matthew Bandurin D A 2022 01 28 Out of equilibrium criticalities in graphene superlattices Science 375 6579 430 433 arXiv 2106 12609 Bibcode 2022Sci 375 430B doi 10 1126 science abi8627 ISSN 0036 8075 PMID 35084955 S2CID 235623859 Schwinger effect seen in graphene Physics World 2022 03 25 Retrieved 2022 03 28 Physicists Prove You Can Make Something out of Nothing by Simulating Cosmic Physics The Debrief 2022 09 19 Retrieved 2023 02 27 Schmitt A Vallet P Mele D Rosticher M Taniguchi T Watanabe K Bocquillon E Feve G Berroir J M Voisin C Cayssol J Goerbig M O Troost J Baudin E Placais B 2023 06 15 Mesoscopic Klein Schwinger effect in graphene Nature Physics 19 6 830 835 arXiv 2207 13400 Bibcode 2023NatPh 19 830S doi 10 1038 s41567 023 01978 9 ISSN 1745 2473 S2CID 251105038 Retrieved from https en wikipedia org w index php title Schwinger effect amp oldid 1198171191, wikipedia, wiki, book, books, library,

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