Glitches in the rotational frequency of a spinning neutron star could be promising sources of gravitational wave signals lasting between a few {\mu}s to a few weeks. The emitted signals and their properties depend upon the internal properties of the neutron star. In stellar models that assume a super-fluid core for the neutron star, the most important physical properties are the viscosity of the super-fluid, the stratification of flow in the equilibrium state and the adiabatic sound speed. Such models were previously studied by van Eysden and Melatos (2008) and Bennett et al. (2010) following simple assumptions on all contributing factors, in which the post-glitch relaxation phase could be driven by the well-known process of 'Ekman pumping'. We explore the hydrodynamic properties of the flow of super-fluid during this phase following more relaxed assumptions on the stratification of flow and/or the pressure-density gradients within the neutron star than previously studied. We calculate the time-scales of duration as well as the characteristic strengths of the resulting gravitational wave signals, and we detail their dependence on the physical properties of the super-fluid core. We find that it is possible for the neutron star to emit gravitational wave signals in a wide range of decay time-scales and within the detection sensitivity of aLIGO for selected domains of physical parameters.
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机译:旋转中子星旋转频率的毛刺可能是引力波信号源,持续时间在几微秒到几周之间。发射的信号及其特性取决于中子星的内部特性。在假设中子星具有超流体核的恒星模型中,最重要的物理属性是超流体的粘度,平衡状态下的流动分层和绝热声速。 van Eysden和Melatos(2008)和Bennett等人以前曾研究过这种模型。 (2010年)遵循所有促成因素的简单假设,其中毛刺后松弛阶段可以由众所周知的“埃克曼抽水”过程驱动。我们按照与先前研究相比对中子星内部的流分层和/或压力密度梯度更宽松的假设,探索了该阶段超流体流动的流体力学特性。我们计算了持续时间的时间尺度以及所产生的引力波信号的特征强度,并详细说明了它们对超流芯物理特性的依赖性。我们发现中子星有可能在很宽的衰减时间范围内并且在aLIGO对选定物理参数域的检测灵敏度范围内发射引力波信号。
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