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Main Authors: Ban, Shoutao, Liu, Helei, Li, Zhaosheng, Chen, Yupeng, Lü, Guoliang, Dohi, Akira, Takeda, Tomoshi, Fan, Hongbin, Zhu, Chunhua, Xu, Renxin
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.12962
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author Ban, Shoutao
Liu, Helei
Li, Zhaosheng
Chen, Yupeng
Lü, Guoliang
Dohi, Akira
Takeda, Tomoshi
Fan, Hongbin
Zhu, Chunhua
Xu, Renxin
author_facet Ban, Shoutao
Liu, Helei
Li, Zhaosheng
Chen, Yupeng
Lü, Guoliang
Dohi, Akira
Takeda, Tomoshi
Fan, Hongbin
Zhu, Chunhua
Xu, Renxin
contents Photosphere radius expansion (PRE) bursts provide a crucial tool for constraining the mass and radius of neutron stars. In this study, we analyze time-resolved spectroscopic data from XTE J1810-189 in 2008, which exhibit evidence of a PRE event. We report here the possibility of a small-size and low-mass neutron star in XTE J1810-189 with use of the advantage of the direct cooling tail method. We obtained three sets of results, which can be broadly divided into high metal abundance (20 $\rm{Z}_{\odot}$ and 40 $\rm{Z}_{\odot}$), low metal abundance and hydrogen-rich (pure hydrogen, $\rm{Z}_{\odot}$, 0.3 $\rm{Z}_{\odot}$, 0.1 $\rm{Z}_{\odot}$, 0.01 $\rm{Z}_{\odot}$), and pure helium. In the high-metallicity scenario, the inferred neutron star mass is $<1.3\,M_{\odot}$ with a radius $<8\,\rm{km}$. In the low-metallicity, hydrogen-rich case, the mass ranges from 0.3 to 2.1 $M_{\odot}$ with radii of 7-13 km. For a pure-helium composition, we find two mass solutions: $1.08_{-0.22}^{+1.32}M_{\odot}$ (with $R>14\,\rm{km}$) and $2.5-2.9\,M_{\odot}$ (above the highest observed neutron star masses). Additionally, we applied the touchdown method combined with an MCMC analysis, the results are consistent with those from the direct cooling tail method, but with a broader range. Our analysis of the time-resolved spectrum of burst suggests a high-metallicity atmosphere, but new observations are required to confirm this result.
format Preprint
id arxiv_https___arxiv_org_abs_2603_12962
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle A low mass and radius neutron star candidate in XTE J1810-189?
Ban, Shoutao
Liu, Helei
Li, Zhaosheng
Chen, Yupeng
Lü, Guoliang
Dohi, Akira
Takeda, Tomoshi
Fan, Hongbin
Zhu, Chunhua
Xu, Renxin
High Energy Astrophysical Phenomena
Photosphere radius expansion (PRE) bursts provide a crucial tool for constraining the mass and radius of neutron stars. In this study, we analyze time-resolved spectroscopic data from XTE J1810-189 in 2008, which exhibit evidence of a PRE event. We report here the possibility of a small-size and low-mass neutron star in XTE J1810-189 with use of the advantage of the direct cooling tail method. We obtained three sets of results, which can be broadly divided into high metal abundance (20 $\rm{Z}_{\odot}$ and 40 $\rm{Z}_{\odot}$), low metal abundance and hydrogen-rich (pure hydrogen, $\rm{Z}_{\odot}$, 0.3 $\rm{Z}_{\odot}$, 0.1 $\rm{Z}_{\odot}$, 0.01 $\rm{Z}_{\odot}$), and pure helium. In the high-metallicity scenario, the inferred neutron star mass is $<1.3\,M_{\odot}$ with a radius $<8\,\rm{km}$. In the low-metallicity, hydrogen-rich case, the mass ranges from 0.3 to 2.1 $M_{\odot}$ with radii of 7-13 km. For a pure-helium composition, we find two mass solutions: $1.08_{-0.22}^{+1.32}M_{\odot}$ (with $R>14\,\rm{km}$) and $2.5-2.9\,M_{\odot}$ (above the highest observed neutron star masses). Additionally, we applied the touchdown method combined with an MCMC analysis, the results are consistent with those from the direct cooling tail method, but with a broader range. Our analysis of the time-resolved spectrum of burst suggests a high-metallicity atmosphere, but new observations are required to confirm this result.
title A low mass and radius neutron star candidate in XTE J1810-189?
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2603.12962