Modeling the X-Ray Emission of the Boomerang Nebula and Implication for Its Potential Ultrahigh-energy Gamma-Ray Emission

Xiao-Bin Chen, Xuan-Han Liang, Ruo-Yu Liu and Xiang-Yu Wang
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Abstract

The Boomerang Nebula is a bright radio and X-ray pulsar wind nebula (PWN) powered by an energetic pulsar, PSR J2229+6114. It is spatially coincident with one of the brightest ultrahigh-energy (UHE; ≥100 TeV) gamma-ray sources, LHAASO J2226+6057. While X-ray observations have provided radial profiles for both the intensity and photon index of the nebula, previous theoretical studies have not reached an agreement on their physical interpretation, which also leads to different anticipation of the UHE emission from the nebula. In this work, we model its X-ray emission with a dynamical evolution model of PWN, considering both convective and diffusive transport of electrons. On the premise of fitting the X-ray intensity and photon index profiles, we find that the magnetic field within the Boomerang Nebula is weak (∼10 μG in the core region and diminishing to 1 μG at the periphery), which therefore implies a significant contribution to the UHE gamma-ray emission by the inverse Compton (IC) radiation of injected electron/positron pairs. Depending on the particle transport mechanism, the UHE gamma-ray flux contributed by the Boomerang Nebula via the IC radiation may constitute about 10%–50% of the flux of LHAASO J2226+6057 at 100 TeV and up to 30% at 500 TeV. Finally, we compare our results with previous studies and discuss potential hadronic UHE emission from the PWN. In our modeling, most of the spindown luminosity of the pulsar may be transformed into thermal particles or relativistic protons.
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回旋星云的 X 射线发射模型及其对潜在超高能伽马射线发射的影响
回旋镖星云是一个明亮的射电和X射线脉冲星风星云(PWN),由一颗高能脉冲星PSR J2229+6114提供能量。它在空间上与最亮的超高能(UHE;≥100 TeV)伽马射线源之一,LHAASO J2226+6057重合。虽然X射线观测提供了该星云的强度和光子指数的径向剖面图,但之前的理论研究并没有就其物理解释达成一致,这也导致了对该星云超高能辐射的不同预期。在这项工作中,我们用PWN的动力学演化模型来模拟它的X射线发射,同时考虑了电子的对流和扩散传输。在拟合X射线强度和光子指数剖面的前提下,我们发现回旋镖星云内部的磁场很弱(核心区为10μG,外围减弱到1μG),这意味着注入的电子/正电子对的反康普顿(IC)辐射对超高温伽马射线辐射有很大的贡献。根据粒子传输机制的不同,回旋镖星云通过IC辐射贡献的超高温伽马射线通量在100TeV时可能占LHAASO J2226+6057通量的10%-50%,在500TeV时高达30%。最后,我们将我们的结果与之前的研究进行了比较,并讨论了来自PWN的潜在强子超高辐射。在我们的建模中,脉冲星的大部分自旋光度可能转化为热粒子或相对论质子。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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