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Autores principales: Pucci, Fulvia, Amato, Elena, Borgogno, Dario, Bucciantini, Niccolo', Innocenti, Maria Elena, Shoeffler, Kevin M, Tavani, Marco, Vittorini, Valerio
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2605.19109
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author Pucci, Fulvia
Amato, Elena
Borgogno, Dario
Bucciantini, Niccolo'
Innocenti, Maria Elena
Shoeffler, Kevin M
Tavani, Marco
Vittorini, Valerio
author_facet Pucci, Fulvia
Amato, Elena
Borgogno, Dario
Bucciantini, Niccolo'
Innocenti, Maria Elena
Shoeffler, Kevin M
Tavani, Marco
Vittorini, Valerio
contents Two-dimensional relativistic particle-in-cell (PIC) simulations of radiative magnetic reconnection in pair plasmas with multiple interacting current sheets are carried out to mimic the dynamics in high-energy astrophysical environments, such as particle acceleration regions in pulsar wind nebulae and relativistic outflows, where the magnetic field is expected to reverse polarity multiple times. Initially, due to reconnection within each isolated sheet, particles are accelerated and synchrotron emission beyond the burn-off limit is confirmed, even if the particle distribution function shows steep slopes. After this phase, plasmoids lead to cross-sheet interactions and merging, with new current sheets formed. In this regime a Kolmogorov-like spectrum for the magnetic energy develops over a couple of decades, followed by a dissipation range starting around 5~$d_e$ (electron inertial lengths), showing that multi-sheet reconnection evolves nonlinearly into well-developed turbulence. This phase provides secondary acceleration and further cooling by synchrotron emission, with intermittent radiative bursts. We show that high energy accelerated particles by the primary current sheets are further energized during the turbulent phase, while the distribution of the most energetic particles remains steep.
format Preprint
id arxiv_https___arxiv_org_abs_2605_19109
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Radiative PIC simulations of relativistic pair plasma: multiple interacting current sheets and turbulent evolution
Pucci, Fulvia
Amato, Elena
Borgogno, Dario
Bucciantini, Niccolo'
Innocenti, Maria Elena
Shoeffler, Kevin M
Tavani, Marco
Vittorini, Valerio
High Energy Astrophysical Phenomena
Plasma Physics
2020: 76W05, 65M75, 82D10, 85A30
Two-dimensional relativistic particle-in-cell (PIC) simulations of radiative magnetic reconnection in pair plasmas with multiple interacting current sheets are carried out to mimic the dynamics in high-energy astrophysical environments, such as particle acceleration regions in pulsar wind nebulae and relativistic outflows, where the magnetic field is expected to reverse polarity multiple times. Initially, due to reconnection within each isolated sheet, particles are accelerated and synchrotron emission beyond the burn-off limit is confirmed, even if the particle distribution function shows steep slopes. After this phase, plasmoids lead to cross-sheet interactions and merging, with new current sheets formed. In this regime a Kolmogorov-like spectrum for the magnetic energy develops over a couple of decades, followed by a dissipation range starting around 5~$d_e$ (electron inertial lengths), showing that multi-sheet reconnection evolves nonlinearly into well-developed turbulence. This phase provides secondary acceleration and further cooling by synchrotron emission, with intermittent radiative bursts. We show that high energy accelerated particles by the primary current sheets are further energized during the turbulent phase, while the distribution of the most energetic particles remains steep.
title Radiative PIC simulations of relativistic pair plasma: multiple interacting current sheets and turbulent evolution
topic High Energy Astrophysical Phenomena
Plasma Physics
2020: 76W05, 65M75, 82D10, 85A30
url https://arxiv.org/abs/2605.19109