Fermion pair radiation from accelerating classical systems

Margarita Gavrilova; Mitrajyoti Ghosh; Yuval Grossman; Walter Tangarife; Tien-Hsueh Tsai

doi:10.1007/JHEP10(2023)002

Fermion pair radiation from accelerating classical systems

Margarita Gavrilova, Mitrajyoti Ghosh, Yuval Grossman, Walter Tangarife, Tien-Hsueh Tsai

Cornell University

Research output: Contribution to journal › Article › peer-review

Abstract

Accelerating classical systems that couple to a fermion-antifermion pair at the microscopic level can radiate pairs of fermions and lose energy in the process. In this work, we derive the generalization of the Larmor formula for fermion pair radiation. We focus on the case of a point-like classical source in an elliptical orbit that emits fermions through vector and scalar mediators. Ultra-light fermion emission from such systems becomes relevant when the mass of the mediator is larger than the frequency of the periodic motion. This enables us to probe regions of the parameter space that are inaccessible in on-shell bosonic radiation. We apply our results to pulsar binaries with mediators that couple to muons and neutrinos. Using current data on binary period decays, we extract bounds on the parameters of such models.

Original language	American English
Journal	Journal of High Energy Physics
DOIs	https://doi.org/10.1007/JHEP10(2023)002
State	Published - Oct 2023

Keywords

fermion
dark matter
neutrinos

Disciplines

Physics

Access to Document

10.1007/JHEP10(2023)002License: Unspecified

Cite this

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title = "Fermion pair radiation from accelerating classical systems",

abstract = " Accelerating classical systems that couple to a fermion-antifermion pair at the microscopic level can radiate pairs of fermions and lose energy in the process. In this work, we derive the generalization of the Larmor formula for fermion pair radiation. We focus on the case of a point-like classical source in an elliptical orbit that emits fermions through vector and scalar mediators. Ultra-light fermion emission from such systems becomes relevant when the mass of the mediator is larger than the frequency of the periodic motion. This enables us to probe regions of the parameter space that are inaccessible in on-shell bosonic radiation. We apply our results to pulsar binaries with mediators that couple to muons and neutrinos. Using current data on binary period decays, we extract bounds on the parameters of such models. ",

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author = "Margarita Gavrilova and Mitrajyoti Ghosh and Yuval Grossman and Walter Tangarife and Tien-Hsueh Tsai",

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T1 - Fermion pair radiation from accelerating classical systems

AU - Gavrilova, Margarita

AU - Ghosh, Mitrajyoti

AU - Grossman, Yuval

AU - Tangarife, Walter

AU - Tsai, Tien-Hsueh

PY - 2023/10

Y1 - 2023/10

N2 - Accelerating classical systems that couple to a fermion-antifermion pair at the microscopic level can radiate pairs of fermions and lose energy in the process. In this work, we derive the generalization of the Larmor formula for fermion pair radiation. We focus on the case of a point-like classical source in an elliptical orbit that emits fermions through vector and scalar mediators. Ultra-light fermion emission from such systems becomes relevant when the mass of the mediator is larger than the frequency of the periodic motion. This enables us to probe regions of the parameter space that are inaccessible in on-shell bosonic radiation. We apply our results to pulsar binaries with mediators that couple to muons and neutrinos. Using current data on binary period decays, we extract bounds on the parameters of such models.

AB - Accelerating classical systems that couple to a fermion-antifermion pair at the microscopic level can radiate pairs of fermions and lose energy in the process. In this work, we derive the generalization of the Larmor formula for fermion pair radiation. We focus on the case of a point-like classical source in an elliptical orbit that emits fermions through vector and scalar mediators. Ultra-light fermion emission from such systems becomes relevant when the mass of the mediator is larger than the frequency of the periodic motion. This enables us to probe regions of the parameter space that are inaccessible in on-shell bosonic radiation. We apply our results to pulsar binaries with mediators that couple to muons and neutrinos. Using current data on binary period decays, we extract bounds on the parameters of such models.

KW - fermion

KW - dark matter

KW - neutrinos

U2 - 10.1007/JHEP10(2023)002

DO - 10.1007/JHEP10(2023)002

M3 - Article

JO - Journal of High Energy Physics

JF - Journal of High Energy Physics

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