相对论磁流体喷流中的粒子。II.将喷流动力学与多波段非热发射特征联系起来

Ravi Pratap Dubey, Christian Fendt and Bhargav Vaidya
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摘要

据观测,源自黑洞附近的相对论磁化喷流表现出亚结构流。在这项研究中,我们展示了不同视线和频率下的合成同步辐射特征,这些特征来自于对 pc 级活动星系核喷流的三维相对论磁流体动力学模拟。这些模拟应用了不同的喷射喷嘴,喷射稳定、可变和前冲射流。在此,我们扩展了之前的研究,开发了一座桥梁,将相对论冲击内的喷流动力学和粒子加速与喷流中占主导地位的非热辐射联系起来。这种辐射来自拉格朗日粒子--它们被注入喷流并跟随流体--通过扩散冲击加速,随后通过同步辐射和反康普顿过程发射能量冷却。总之,不同的冲击结构会形成许多局部发射模式--被解释为喷流节。这些喷流结图案可能会消退或耀斑,也可能是合并或多普勒增强的结果,从而导致喷流变异。我们发现的节具有足够高的模式速度,可以被认为是可见的超光速运动≲5c。所有喷流的同步辐射光谱都显示了双驼峰结构,反映了多个电子群,其特征与底层冲击的性质及其年龄有关。前冲喷流是最强大的发射体,其光谱比稳定喷流和可变喷流更平坦。这种发射虽然主要受冲击加速度的影响,但也取决于粒子的冷却历史。总之,我们发现电子通过沿射流的冲击持续再加速是观测大时间尺度和长度尺度的扩展射流发射的必要先决条件。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Particles in Relativistic Magnetohydrodynamic Jets. II. Bridging Jet Dynamics with Multi–wave band Nonthermal Emission Signatures
Relativistic magnetized jets, originating near black holes, are observed to exhibit substructured flows. In this study, we present synthetic synchrotron-emission signatures for different lines of sight and frequencies, derived from three-dimensional relativistic magnetohydrodynamic simulations of pc-scale Active Galactic Nuclei jets. These simulations apply different injection nozzles, injecting steady, variable, and precessing jets. Extending our previous study, here, we have developed a bridge to connect jet dynamics and particle acceleration within relativistic shocks with nonthermal radiation dominant in jets. The emission is derived from Lagrangian particles—injected into the jet and following the fluid—accelerated through diffusive shock acceleration and subsequently cooled by emitting energy via synchrotron and inverse-Compton processes. Overall, the different shock structures lead to the formation of numerous localized emission patterns—interpreted as jet knots. These knot patterns can fade or flare, also as a consequence of merging or Doppler boosting, leading to jet variability. We find knots with high-enough pattern speed supposed to be visible as superluminal motion ≲5c. Synchrotron spectra of all jets reveal double-humped structures, reflecting multiple electron populations characterized by the nature of underlying shock and their age. The precessing jet is the most powerful emitter, featuring a spectrum flatter than the steady and the variable jet. The emission, although essentially governed by the acceleration through shocks, depends on the cooling history of the particle as well. Overall, the continuous reacceleration of electrons through shocks along the jet we found is an essential prerequisite for observing extended jet emission over large timescales and length scales.
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