The saturation mechanism of thermal instability

IF 2.6 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS Frontiers in Astronomy and Space Sciences Pub Date : 2023-10-16 DOI:10.3389/fspas.2023.1198135
Tim Waters, Daniel Proga
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Abstract

The literature on thermal instability (TI) reveals that even for a simple homogeneous plasma, the nonlinear outcome ranges from a gentle reconfiguration of the initial state to an explosive one, depending on whether the condensations that form evolve in an isobaric or nonisobaric manner. After summarizing the recent developments on the linear and nonlinear theory of TI, here we derive several general identities from the evolution equation for entropy that reveal the mechanism by which TI saturates; whenever the boundary of the instability region (the Balbus contour) is crossed, a dynamical change is triggered that causes the comoving time derivative of the pressure to change the sign. This event implies that the gas pressure force reverses direction, slowing the continued growth of condensation. For isobaric evolution, this “pressure reversal” occurs nearly simultaneously for every fluid element in condensation and a steady state is quickly reached. For nonisobaric evolution, the condensation is no longer in mechanical equilibrium and the contracting gas rebounds with greater force during the expansion phase that accompanies the gas reaching the equilibrium curve. The cloud then pulsates because the return to mechanical equilibrium becomes wave mediated. We show that both the contraction rebound event and subsequent pulsation behavior follow analytically from an analysis of the new identities. Our analysis also leads to the identification of an isochoric TI zone and makes it clear that unless this zone intersects the equilibrium curve, isochoric modes can only become unstable if the plasma is in a state of thermal non-equilibrium.
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热不稳定性的饱和机理
关于热不稳定性(TI)的文献表明,即使是简单的均匀等离子体,其非线性结果也从初始状态的温和重新配置到爆炸状态,这取决于形成的凝聚是否以等压或非等压方式演化。在总结了TI的线性和非线性理论的最新发展之后,我们从熵的演化方程中导出了几个通用恒等式,揭示了TI饱和的机制;每当不稳定区域的边界(Balbus轮廓)被越过时,就会触发一个动态变化,使压力的运动时间导数改变符号。这一事件表明,气体压力力的方向相反,减缓了冷凝的持续增长。对于等压演化,这种“压力反转”几乎同时发生在冷凝中的每一种流体元素上,并迅速达到稳定状态。对于非等压演化,冷凝不再处于力学平衡状态,在气体到达平衡曲线的膨胀阶段,收缩气体以更大的力反弹。然后云团会脉动,因为回归到机械平衡的过程会以波为媒介。通过对新恒等式的分析,我们证明了收缩反弹事件和随后的脉动行为的解析性。我们的分析还导致了TI等共线区的识别,并清楚地表明,除非该区域与平衡曲线相交,否则等共线模式只有在等离子体处于热非平衡状态时才会变得不稳定。
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来源期刊
Frontiers in Astronomy and Space Sciences
Frontiers in Astronomy and Space Sciences ASTRONOMY & ASTROPHYSICS-
CiteScore
3.40
自引率
13.30%
发文量
363
审稿时长
14 weeks
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