Backreaction of Schwinger pair creation in massive QED(2)

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Backreaction of Schwinger pair creation in massive QED(2). / Gold, Gregory; McGady, David A.; Patil, Subodh P.; Vardanyan, Valeri.

In: Journal of High Energy Physics, Vol. 2021, No. 10, 072, 08.10.2021.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Gold, G, McGady, DA, Patil, SP & Vardanyan, V 2021, 'Backreaction of Schwinger pair creation in massive QED(2)', Journal of High Energy Physics, vol. 2021, no. 10, 072. https://doi.org/10.1007/JHEP10(2021)072

APA

Gold, G., McGady, D. A., Patil, S. P., & Vardanyan, V. (2021). Backreaction of Schwinger pair creation in massive QED(2). Journal of High Energy Physics, 2021(10), [072]. https://doi.org/10.1007/JHEP10(2021)072

Vancouver

Gold G, McGady DA, Patil SP, Vardanyan V. Backreaction of Schwinger pair creation in massive QED(2). Journal of High Energy Physics. 2021 Oct 8;2021(10). 072. https://doi.org/10.1007/JHEP10(2021)072

Author

Gold, Gregory ; McGady, David A. ; Patil, Subodh P. ; Vardanyan, Valeri. / Backreaction of Schwinger pair creation in massive QED(2). In: Journal of High Energy Physics. 2021 ; Vol. 2021, No. 10.

Bibtex

@article{8de4a8f38c034092a3d03f253df1ac21,
title = "Backreaction of Schwinger pair creation in massive QED(2)",
abstract = "Particle-antiparticle pairs can be produced by background electric fields via the Schwinger mechanism provided they are unconfined. If, as in QED in (3+1)-d these particles are massive, the particle production rate is exponentially suppressed below a threshold field strength. Above this threshold, the energy for pair creation must come from the electric field itself which ought to eventually relax to the threshold strength. Calculating this relaxation in a self-consistent manner, however, is difficult. Chu and Vachaspati addressed this problem in the context of capacitor discharge in massless QED(2) [1] by utilizing bosonization in two-dimensions. When the bare fermions are massless, the dual bosonized theory is free and capacitor discharge can be analyzed exactly [1], however, special care is required in its interpretation given that the theory exhibits confinement. In this paper we reinterpret the findings of [1], where the capacitors Schwinger-discharge via electrically neutral dipolar meson-production, and generalize this to the case where the fermions have bare masses. Crucially, we note that when the initial charge of the capacitor is large compared to the charge of the fermions, Q >> e, the classical equation of motion for the bosonized model accurately characterizes the dynamics of discharge. For massless QED(2), we find that the discharge is suppressed below a critical plate separation that is commensurate with the length scale associated with the meson dipole moment. For massive QED(2), we find in addition, a mass threshold familiar from (3+1)-d, and show the electric field relaxes to a final steady state with a magnitude proportional to the initial charge. We discuss the wider implications of our findings and identify challenges in extending this treatment to higher dimensions.",
keywords = "Field Theories in Lower Dimensions, Nonperturbative Effects, GAUGE-INVARIANCE, BACK-REACTION, FIELD-THEORY, CONFINEMENT, EQUATION",
author = "Gregory Gold and McGady, {David A.} and Patil, {Subodh P.} and Valeri Vardanyan",
year = "2021",
month = oct,
day = "8",
doi = "10.1007/JHEP10(2021)072",
language = "English",
volume = "2021",
journal = "Journal of High Energy Physics (Online)",
issn = "1126-6708",
publisher = "Springer",
number = "10",

}

RIS

TY - JOUR

T1 - Backreaction of Schwinger pair creation in massive QED(2)

AU - Gold, Gregory

AU - McGady, David A.

AU - Patil, Subodh P.

AU - Vardanyan, Valeri

PY - 2021/10/8

Y1 - 2021/10/8

N2 - Particle-antiparticle pairs can be produced by background electric fields via the Schwinger mechanism provided they are unconfined. If, as in QED in (3+1)-d these particles are massive, the particle production rate is exponentially suppressed below a threshold field strength. Above this threshold, the energy for pair creation must come from the electric field itself which ought to eventually relax to the threshold strength. Calculating this relaxation in a self-consistent manner, however, is difficult. Chu and Vachaspati addressed this problem in the context of capacitor discharge in massless QED(2) [1] by utilizing bosonization in two-dimensions. When the bare fermions are massless, the dual bosonized theory is free and capacitor discharge can be analyzed exactly [1], however, special care is required in its interpretation given that the theory exhibits confinement. In this paper we reinterpret the findings of [1], where the capacitors Schwinger-discharge via electrically neutral dipolar meson-production, and generalize this to the case where the fermions have bare masses. Crucially, we note that when the initial charge of the capacitor is large compared to the charge of the fermions, Q >> e, the classical equation of motion for the bosonized model accurately characterizes the dynamics of discharge. For massless QED(2), we find that the discharge is suppressed below a critical plate separation that is commensurate with the length scale associated with the meson dipole moment. For massive QED(2), we find in addition, a mass threshold familiar from (3+1)-d, and show the electric field relaxes to a final steady state with a magnitude proportional to the initial charge. We discuss the wider implications of our findings and identify challenges in extending this treatment to higher dimensions.

AB - Particle-antiparticle pairs can be produced by background electric fields via the Schwinger mechanism provided they are unconfined. If, as in QED in (3+1)-d these particles are massive, the particle production rate is exponentially suppressed below a threshold field strength. Above this threshold, the energy for pair creation must come from the electric field itself which ought to eventually relax to the threshold strength. Calculating this relaxation in a self-consistent manner, however, is difficult. Chu and Vachaspati addressed this problem in the context of capacitor discharge in massless QED(2) [1] by utilizing bosonization in two-dimensions. When the bare fermions are massless, the dual bosonized theory is free and capacitor discharge can be analyzed exactly [1], however, special care is required in its interpretation given that the theory exhibits confinement. In this paper we reinterpret the findings of [1], where the capacitors Schwinger-discharge via electrically neutral dipolar meson-production, and generalize this to the case where the fermions have bare masses. Crucially, we note that when the initial charge of the capacitor is large compared to the charge of the fermions, Q >> e, the classical equation of motion for the bosonized model accurately characterizes the dynamics of discharge. For massless QED(2), we find that the discharge is suppressed below a critical plate separation that is commensurate with the length scale associated with the meson dipole moment. For massive QED(2), we find in addition, a mass threshold familiar from (3+1)-d, and show the electric field relaxes to a final steady state with a magnitude proportional to the initial charge. We discuss the wider implications of our findings and identify challenges in extending this treatment to higher dimensions.

KW - Field Theories in Lower Dimensions

KW - Nonperturbative Effects

KW - GAUGE-INVARIANCE

KW - BACK-REACTION

KW - FIELD-THEORY

KW - CONFINEMENT

KW - EQUATION

U2 - 10.1007/JHEP10(2021)072

DO - 10.1007/JHEP10(2021)072

M3 - Journal article

VL - 2021

JO - Journal of High Energy Physics (Online)

JF - Journal of High Energy Physics (Online)

SN - 1126-6708

IS - 10

M1 - 072

ER -

ID: 282474310