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Main Authors: Russell, Brandon K., Qian, Qian, Fitzgarrald, Rebecca, Zhang, Yang, Bulanov, Stepan S., Bulanov, Sergei V., Chen, Hui, Gao, Lan, Grittani, Gabriele M., Li, Xiaocan, Orr, Kian, Pomraning, Geoffrey, Schoeffler, Kevin M., Thomas, Alexander G. R., Ji, Hantao
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.17127
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author Russell, Brandon K.
Qian, Qian
Fitzgarrald, Rebecca
Zhang, Yang
Bulanov, Stepan S.
Bulanov, Sergei V.
Chen, Hui
Gao, Lan
Grittani, Gabriele M.
Li, Xiaocan
Orr, Kian
Pomraning, Geoffrey
Schoeffler, Kevin M.
Thomas, Alexander G. R.
Ji, Hantao
author_facet Russell, Brandon K.
Qian, Qian
Fitzgarrald, Rebecca
Zhang, Yang
Bulanov, Stepan S.
Bulanov, Sergei V.
Chen, Hui
Gao, Lan
Grittani, Gabriele M.
Li, Xiaocan
Orr, Kian
Pomraning, Geoffrey
Schoeffler, Kevin M.
Thomas, Alexander G. R.
Ji, Hantao
contents We propose and simulate a laboratory platform to study the effects of positrons in magnetic reconnection using laser-driven capacitor coils. Using particle-in-cell simulations, we show that externally injected MeV electron-positron pairs are trapped in the coil current sheet, significantly modifying the reconnection dynamics and particle acceleration. These pairs increase the reconnection rate by a factor of approximately 8, which Ohm's law decomposition reveals to be driven by the divergence of the generalized pressure tensor. Based on their high energy and magnetization, the pairs also substantially broaden the diffusion region. Particle tracking simulations in realistic coil magnetic fields further demonstrate that injected pairs can remain confined for several picoseconds, providing conditions for sustained interaction with the reconnection region. These results establish a near-term pathway to laboratory studies of positron-influenced reconnection, bridging high-energy-density experiments with pair-dominated astrophysical environments.
format Preprint
id arxiv_https___arxiv_org_abs_2603_17127
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Pair-loaded electron-only magnetic reconnection using laser-driven capacitor coils
Russell, Brandon K.
Qian, Qian
Fitzgarrald, Rebecca
Zhang, Yang
Bulanov, Stepan S.
Bulanov, Sergei V.
Chen, Hui
Gao, Lan
Grittani, Gabriele M.
Li, Xiaocan
Orr, Kian
Pomraning, Geoffrey
Schoeffler, Kevin M.
Thomas, Alexander G. R.
Ji, Hantao
Plasma Physics
We propose and simulate a laboratory platform to study the effects of positrons in magnetic reconnection using laser-driven capacitor coils. Using particle-in-cell simulations, we show that externally injected MeV electron-positron pairs are trapped in the coil current sheet, significantly modifying the reconnection dynamics and particle acceleration. These pairs increase the reconnection rate by a factor of approximately 8, which Ohm's law decomposition reveals to be driven by the divergence of the generalized pressure tensor. Based on their high energy and magnetization, the pairs also substantially broaden the diffusion region. Particle tracking simulations in realistic coil magnetic fields further demonstrate that injected pairs can remain confined for several picoseconds, providing conditions for sustained interaction with the reconnection region. These results establish a near-term pathway to laboratory studies of positron-influenced reconnection, bridging high-energy-density experiments with pair-dominated astrophysical environments.
title Pair-loaded electron-only magnetic reconnection using laser-driven capacitor coils
topic Plasma Physics
url https://arxiv.org/abs/2603.17127