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Main Authors: Li, Xiao, Liang, En-Wei
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.19315
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author Li, Xiao
Liang, En-Wei
author_facet Li, Xiao
Liang, En-Wei
contents The temporal and spatial coincidence between FRB 20200428 and hard peaks of the X-ray burst from SGR 1935+2154 suggests their potential association. We attributed them to the plasma synchrotron maser emission and synchrotron radiation of electrons in weakly magnetized, relativistically moving plasma blobs, and Monte Carlo simulation analysis shows that our model can predict observable fast radio burst outbursts and associated hard X-ray bursts with current telescopes. We constrained the properties of the blobs, including the Lorentz factor $Γ=5-30$, the magnetization factor $σ=6\times10^{-5}\sim 2\times 10^{-4}$, the electron Lorentz factor $γ_{\rm e,s}=(1.8-3.3)\times10^4$, and the plasma frequency $ν_P=2.48 -42.61$ MHz. The inferred size of the blobs is $\sim 10^{9-10}$ cm, and it is located $\sim 10^{12-14}$ cm from the central engine. By adopting fine-tuned parameter sets, the observed spectra of both the FRB 20200428 outbursts and X-ray bursts can be well represented. The peak flux density ($F_{\rmν_{ pk}}$) of plasma maser emission is sensitive to $σ$ and $ν_P$. Variation in $F_{\rm ν_{pk}}$ can be more than 10 orders of magnitude, while the flux density of the synchrotron emission only varies by $1-2$ orders of magnitude. This can account for the observed sub-energetic radio bursts or giant radio pulses from SGR 1935+2154.
format Preprint
id arxiv_https___arxiv_org_abs_2508_19315
institution arXiv
publishDate 2025
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spellingShingle FRB 20200428 and potentially associated hard X-ray bursts: Maser emission and synchrotron radiation of electrons in a weakly magnetized plasma?
Li, Xiao
Liang, En-Wei
High Energy Astrophysical Phenomena
The temporal and spatial coincidence between FRB 20200428 and hard peaks of the X-ray burst from SGR 1935+2154 suggests their potential association. We attributed them to the plasma synchrotron maser emission and synchrotron radiation of electrons in weakly magnetized, relativistically moving plasma blobs, and Monte Carlo simulation analysis shows that our model can predict observable fast radio burst outbursts and associated hard X-ray bursts with current telescopes. We constrained the properties of the blobs, including the Lorentz factor $Γ=5-30$, the magnetization factor $σ=6\times10^{-5}\sim 2\times 10^{-4}$, the electron Lorentz factor $γ_{\rm e,s}=(1.8-3.3)\times10^4$, and the plasma frequency $ν_P=2.48 -42.61$ MHz. The inferred size of the blobs is $\sim 10^{9-10}$ cm, and it is located $\sim 10^{12-14}$ cm from the central engine. By adopting fine-tuned parameter sets, the observed spectra of both the FRB 20200428 outbursts and X-ray bursts can be well represented. The peak flux density ($F_{\rmν_{ pk}}$) of plasma maser emission is sensitive to $σ$ and $ν_P$. Variation in $F_{\rm ν_{pk}}$ can be more than 10 orders of magnitude, while the flux density of the synchrotron emission only varies by $1-2$ orders of magnitude. This can account for the observed sub-energetic radio bursts or giant radio pulses from SGR 1935+2154.
title FRB 20200428 and potentially associated hard X-ray bursts: Maser emission and synchrotron radiation of electrons in a weakly magnetized plasma?
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2508.19315