Constraining the Properties of GRB Accreting Magnetar with R/I Evolutionary Effects Using Swift/XRT Data
Abstract
A newly born millisecond magnetar has been proposed as one possible central engine of some long gamma-ray bursts (LGRBs) with X-ray plateau. In this work, we used a universal correlation between initial spin period (P0) and surface magnetic field (Bp) of newborn magnetar based on an LGRB sample in Lan2025 to explore the propeller properties of accreting magnetars with R/I evolutionary effects. We found that Bp-P0 relation is approximately consistent with Bp P eq7/6. Here P eq is equilibrium spin period in magnetic propeller model. The Bp-P0 relation indicates that P0 may not be true initial spin period of newborn magnetar but had reached an equilibrium spin period via fallback accretion in propeller model. The magnetar accretion rate in our LGRBs is in range of M10-5-10-2 M s-1 by incorporating R/I evolutionary effects and using the transition relation between gravitational mass Mg and baryonic mass Mb in different equations of state. Such accretion rates ensure that the accreting magnetars in our sample survive until reaching the equilibrium spin period, and the accretion rate is one order of magnitude lower compared to the statistical results in Stratta2018 and Linweili2020, which used constant R/I/Mg scenario. We suggested that adopting a constant R/I/Mg scenario for modeling propeller regime in accreting magnetar results in a higher mass accretion rate, which may impair our understanding of the physical nature and its surroundings of accreting magnetar, and low-metallicity progenitors can provide enough material to satisfy the accretion requirements of newborn accreting magnetar in LGRBs.
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