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Main Authors: Ye, Dingyi, Chen, Alexander Y.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.15804
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author Ye, Dingyi
Chen, Alexander Y.
author_facet Ye, Dingyi
Chen, Alexander Y.
contents Recent developments in the study of pulsar radio emission revealed that the microphysics of quantum electrodynamic (QED) pair cascades at pulsar polar caps may be responsible for generating the observed coherent radio waves. However, modeling the pair cascades in the polar cap region poses significant challenges, particularly under conditions of high plasma multiplicity. Traditional Particle-in-Cell (PIC) methods often face rapidly increasing computational costs as the multiplicity grows exponentially. To address this issue, we present a new simulation code using the Vlasov method, which efficiently simulates the evolution of charged particle distribution functions in phase space without a proportional increase in computational expense at high multiplicities. We apply this code to study $e^\pm$ pair cascades in 1D, incorporating key physical processes such as curvature radiation, radiative cooling, and magnetic pair production. We study both the Ruderman-Sutherland (RS) and the Space-charge-limited Flow (SCLF) regimes, and find quasiperiodic gap formation and pair production bursts in both cases. These features produce strong electric field oscillations, potentially enabling coherent low-frequency radio emission. We construct a unified analytic model that describes the key features of the polar cap cascade, which can be used to estimate the return current heating rate that can be used to inform X-ray hotspot models. Spectral analysis shows that a significant amount of energy is carried in superluminal modes -- collective excitations that could connect to observed radio features. Our results align with previous PIC studies while offering enhanced fidelity in both dense and rarefied regions.
format Preprint
id arxiv_https___arxiv_org_abs_2507_15804
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle 1D Vlasov Simulations of QED Cascades Over Pulsar Polar Caps
Ye, Dingyi
Chen, Alexander Y.
High Energy Astrophysical Phenomena
Recent developments in the study of pulsar radio emission revealed that the microphysics of quantum electrodynamic (QED) pair cascades at pulsar polar caps may be responsible for generating the observed coherent radio waves. However, modeling the pair cascades in the polar cap region poses significant challenges, particularly under conditions of high plasma multiplicity. Traditional Particle-in-Cell (PIC) methods often face rapidly increasing computational costs as the multiplicity grows exponentially. To address this issue, we present a new simulation code using the Vlasov method, which efficiently simulates the evolution of charged particle distribution functions in phase space without a proportional increase in computational expense at high multiplicities. We apply this code to study $e^\pm$ pair cascades in 1D, incorporating key physical processes such as curvature radiation, radiative cooling, and magnetic pair production. We study both the Ruderman-Sutherland (RS) and the Space-charge-limited Flow (SCLF) regimes, and find quasiperiodic gap formation and pair production bursts in both cases. These features produce strong electric field oscillations, potentially enabling coherent low-frequency radio emission. We construct a unified analytic model that describes the key features of the polar cap cascade, which can be used to estimate the return current heating rate that can be used to inform X-ray hotspot models. Spectral analysis shows that a significant amount of energy is carried in superluminal modes -- collective excitations that could connect to observed radio features. Our results align with previous PIC studies while offering enhanced fidelity in both dense and rarefied regions.
title 1D Vlasov Simulations of QED Cascades Over Pulsar Polar Caps
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2507.15804