Worldline modeling of ultra-intense lasers for N-photon scattering processes

I. Ahumada; P. Copinger; J. P. Edwards; K. Rajeev

doi:10.1063/5.0273358

Worldline modeling of ultra-intense lasers for N-photon scattering processes

I. Ahumada, P. Copinger^*, J. P. Edwards, K. Rajeev

^*Corresponding author for this work

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Abstract

The modeling of present and future ultra-intense lasers demands techniques that go beyond the standard diagrammatic approach to non-perturbatively fully capture the effects of strong fields. We illustrate the first-quantized path integral representation for strong-field quantum electrodynamics as a means of accessing the laser being treated as a background field, which is treated without recourse to perturbation theory. We examine an all-multiplicity construction for N-photon scattering processes for complex scalars and spinors, showing compact Master Formulae for tree-level scattering. Several background fields are considered, including plane waves, impulsive parallel propagation waves, non-null fields, and homogeneous fields (constant-crossed fields) with low-energy external photons.

Original language	English
Article number	073901
Journal	Physics of Plasmas
Volume	32
Issue number	7
DOIs	https://doi.org/10.1063/5.0273358
Publication status	Published - 1 Jul 2025

ASJC Scopus subject areas

Condensed Matter Physics

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10.1063/5.0273358

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title = "Worldline modeling of ultra-intense lasers for N-photon scattering processes",

abstract = "The modeling of present and future ultra-intense lasers demands techniques that go beyond the standard diagrammatic approach to non-perturbatively fully capture the effects of strong fields. We illustrate the first-quantized path integral representation for strong-field quantum electrodynamics as a means of accessing the laser being treated as a background field, which is treated without recourse to perturbation theory. We examine an all-multiplicity construction for N-photon scattering processes for complex scalars and spinors, showing compact Master Formulae for tree-level scattering. Several background fields are considered, including plane waves, impulsive parallel propagation waves, non-null fields, and homogeneous fields (constant-crossed fields) with low-energy external photons.",

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AU - Ahumada, I.

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AU - Rajeev, K.

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Y1 - 2025/7/1

N2 - The modeling of present and future ultra-intense lasers demands techniques that go beyond the standard diagrammatic approach to non-perturbatively fully capture the effects of strong fields. We illustrate the first-quantized path integral representation for strong-field quantum electrodynamics as a means of accessing the laser being treated as a background field, which is treated without recourse to perturbation theory. We examine an all-multiplicity construction for N-photon scattering processes for complex scalars and spinors, showing compact Master Formulae for tree-level scattering. Several background fields are considered, including plane waves, impulsive parallel propagation waves, non-null fields, and homogeneous fields (constant-crossed fields) with low-energy external photons.

AB - The modeling of present and future ultra-intense lasers demands techniques that go beyond the standard diagrammatic approach to non-perturbatively fully capture the effects of strong fields. We illustrate the first-quantized path integral representation for strong-field quantum electrodynamics as a means of accessing the laser being treated as a background field, which is treated without recourse to perturbation theory. We examine an all-multiplicity construction for N-photon scattering processes for complex scalars and spinors, showing compact Master Formulae for tree-level scattering. Several background fields are considered, including plane waves, impulsive parallel propagation waves, non-null fields, and homogeneous fields (constant-crossed fields) with low-energy external photons.

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JO - Physics of Plasmas

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IS - 7

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ER -

Worldline modeling of ultra-intense lasers for N-photon scattering processes

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