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Main Authors: Liu, Jiaxin, Yuan, Haoyu, Lei, Xiangli, Xu, Wenlong, Takata, Jumpei, Lei, Weihua
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.10514
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author Liu, Jiaxin
Yuan, Haoyu
Lei, Xiangli
Xu, Wenlong
Takata, Jumpei
Lei, Weihua
author_facet Liu, Jiaxin
Yuan, Haoyu
Lei, Xiangli
Xu, Wenlong
Takata, Jumpei
Lei, Weihua
contents We investigate the optical linear polarization caused by Thomson scattering of the stellar radiation for gamma-ray binary \lsi61, which likely contains a young pulsar. Based on the pulsar binary scenario, we model the interaction between the pulsar wind and stellar wind from the massive companion star, which creates a shock. To accurately compute the resulting polarization of the stellar wind, we develop a method for the Thomson scattering that accounts for the finite size of the companion star. By fitting the optical polarization data, we constrain the system parameters, such as eccentricity, the momentum ratio of the two winds, and mass-loss rate from the companion star. We find that (i) the predicted eccentricity $e\sim 0.1$ is smaller than the values derived from the radial velocity curve and (ii) the orbital phase of the periastron is $ν_{\rm p}=0.5-0.6$, which is consistent with the previous polarization study of Kravtsov et al. Additionally, we estimate the mass-loss rate from the companion star and the momentum ratio of two winds as $\dot{M}\sim 2\times 10^{-6}\rm M_{\odot}~{\rm year^{-1}}$ and $η>0.1$, respectively. Assuming that the pulsar wind carries the spin-down energy, the spin-down magnetic field of the putative pulsar inferred from these parameters is of the order of $B\sim 10^{14}\mathrm{G}$, which may support the highly-B pulsar or magnetar scenario for the compact object of $\rm{LS\ I} +61^{\circ}303$. We also discuss the dispersion measure under the predicted orbital geometry and provide a corresponding interpretation of the pulsed radio signal detected by FAST.
format Preprint
id arxiv_https___arxiv_org_abs_2510_10514
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Investigation for binary characteristics of LS I+61303 with optical polarization
Liu, Jiaxin
Yuan, Haoyu
Lei, Xiangli
Xu, Wenlong
Takata, Jumpei
Lei, Weihua
High Energy Astrophysical Phenomena
We investigate the optical linear polarization caused by Thomson scattering of the stellar radiation for gamma-ray binary \lsi61, which likely contains a young pulsar. Based on the pulsar binary scenario, we model the interaction between the pulsar wind and stellar wind from the massive companion star, which creates a shock. To accurately compute the resulting polarization of the stellar wind, we develop a method for the Thomson scattering that accounts for the finite size of the companion star. By fitting the optical polarization data, we constrain the system parameters, such as eccentricity, the momentum ratio of the two winds, and mass-loss rate from the companion star. We find that (i) the predicted eccentricity $e\sim 0.1$ is smaller than the values derived from the radial velocity curve and (ii) the orbital phase of the periastron is $ν_{\rm p}=0.5-0.6$, which is consistent with the previous polarization study of Kravtsov et al. Additionally, we estimate the mass-loss rate from the companion star and the momentum ratio of two winds as $\dot{M}\sim 2\times 10^{-6}\rm M_{\odot}~{\rm year^{-1}}$ and $η>0.1$, respectively. Assuming that the pulsar wind carries the spin-down energy, the spin-down magnetic field of the putative pulsar inferred from these parameters is of the order of $B\sim 10^{14}\mathrm{G}$, which may support the highly-B pulsar or magnetar scenario for the compact object of $\rm{LS\ I} +61^{\circ}303$. We also discuss the dispersion measure under the predicted orbital geometry and provide a corresponding interpretation of the pulsed radio signal detected by FAST.
title Investigation for binary characteristics of LS I+61303 with optical polarization
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2510.10514