Light-Matter Interaction near the Schwinger Limit Using Tightly Focused Doppler-Boosted Lasers

Neïl Zaïm; Antonin Sainte-Marie; Luca Fedeli; Pierre Bartoli; Axel Huebl; Adrien Leblanc; Jean Luc Vay; Henri Vincenti

doi:10.1103/PhysRevLett.132.175002

Light-Matter Interaction near the Schwinger Limit Using Tightly Focused Doppler-Boosted Lasers

Neïl Zaïm
, Antonin Sainte-Marie
, Luca Fedeli
, Pierre Bartoli
, Axel Huebl
, Adrien Leblanc
, Jean Luc Vay
, Henri Vincenti

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

Abstract

Strong-field quantum electrodynamics (SF QED) is a burgeoning research topic dealing with electromagnetic fields comparable to the Schwinger field (≈1.32×1018 V/m). While most past and proposed experiments rely on reaching this field in the rest frame of relativistic particles, the Schwinger limit could also be approached in the laboratory frame by focusing to its diffraction limit the light reflected by a plasma mirror irradiated by a multipetawatt laser. We explore the interaction between such intense light and matter with particle-in-cell simulations. We find that the collision with a relativistic electron beam would enable the study of the nonperturbative regime of SF QED, while the interaction with a solid target leads to a profusion of SF QED effects that retroact on the interaction. In both cases, relativistic attosecond pair jets with high densities are formed.

Original language	English
Article number	175002
Journal	Physical Review Letters
Volume	132
Issue number	17
DOIs	https://doi.org/10.1103/PhysRevLett.132.175002
Publication status	Published - 26 Apr 2024

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10.1103/PhysRevLett.132.175002

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title = "Light-Matter Interaction near the Schwinger Limit Using Tightly Focused Doppler-Boosted Lasers",

abstract = "Strong-field quantum electrodynamics (SF QED) is a burgeoning research topic dealing with electromagnetic fields comparable to the Schwinger field (≈1.32×1018 V/m). While most past and proposed experiments rely on reaching this field in the rest frame of relativistic particles, the Schwinger limit could also be approached in the laboratory frame by focusing to its diffraction limit the light reflected by a plasma mirror irradiated by a multipetawatt laser. We explore the interaction between such intense light and matter with particle-in-cell simulations. We find that the collision with a relativistic electron beam would enable the study of the nonperturbative regime of SF QED, while the interaction with a solid target leads to a profusion of SF QED effects that retroact on the interaction. In both cases, relativistic attosecond pair jets with high densities are formed.",

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AU - Zaïm, Neïl

AU - Sainte-Marie, Antonin

AU - Fedeli, Luca

AU - Bartoli, Pierre

AU - Huebl, Axel

AU - Leblanc, Adrien

AU - Vay, Jean Luc

AU - Vincenti, Henri

PY - 2024/4/26

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N2 - Strong-field quantum electrodynamics (SF QED) is a burgeoning research topic dealing with electromagnetic fields comparable to the Schwinger field (≈1.32×1018 V/m). While most past and proposed experiments rely on reaching this field in the rest frame of relativistic particles, the Schwinger limit could also be approached in the laboratory frame by focusing to its diffraction limit the light reflected by a plasma mirror irradiated by a multipetawatt laser. We explore the interaction between such intense light and matter with particle-in-cell simulations. We find that the collision with a relativistic electron beam would enable the study of the nonperturbative regime of SF QED, while the interaction with a solid target leads to a profusion of SF QED effects that retroact on the interaction. In both cases, relativistic attosecond pair jets with high densities are formed.

AB - Strong-field quantum electrodynamics (SF QED) is a burgeoning research topic dealing with electromagnetic fields comparable to the Schwinger field (≈1.32×1018 V/m). While most past and proposed experiments rely on reaching this field in the rest frame of relativistic particles, the Schwinger limit could also be approached in the laboratory frame by focusing to its diffraction limit the light reflected by a plasma mirror irradiated by a multipetawatt laser. We explore the interaction between such intense light and matter with particle-in-cell simulations. We find that the collision with a relativistic electron beam would enable the study of the nonperturbative regime of SF QED, while the interaction with a solid target leads to a profusion of SF QED effects that retroact on the interaction. In both cases, relativistic attosecond pair jets with high densities are formed.

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ER -

Light-Matter Interaction near the Schwinger Limit Using Tightly Focused Doppler-Boosted Lasers

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