Sufficiency of near-surface water ice as a driver of dust activity on comets. Rethinking the old enigma

Y. Skorov, O. Mokhtari, W. Macher, V. Reshetnyk, J. Markkanen, Y. Zhao, N. Thomas, M. Kuppers, P. Hartogh
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Abstract

Nearly all contemporary theoretical research on cometary dust activity relies on models depicting heat transfer and sublimation products within the near-surface porous layer. Gas flow exerts a pressure drag to the crust agglomerates, counteracting weak gravity and the tensile strength of that layer. Our interpretation of data from the Rosetta mission, and our broader comprehension of cometary activity, hinges significantly on the study of this process. We investigate the role played by the structure of the near-surface porous layer and its associated resistance to gas flow, tensile strength, pressure distribution, and other characteristics in the scenario of the potential release of dust agglomerates and the resulting dust activity. We employ a thermophysical model that factors in the microstructure of this layer and radiative heat conductivity. We consider gas flow in both the Knudsen and transition regimes. To accomplish this, we use methods such as test-particles Monte Carlo, direct-simulation Monte Carlo, and transmission probability. Our study encompasses a broad spectrum of dust-particle sizes. We evaluated the permeability of a dust layer composed of porous aggregates in the submillimetre and millimetre ranges. We carried out comparisons among various models that describe gas diffusion in a porous dust layer. For both the transition and Knudsen regimes, we obtained pressure profiles within a non-isothermal layer. We discuss how the gaps in our understanding of the structure and composition could impact tensile strength estimates. We demonstrate that for particles in the millimetre range, the lifting force of the sublimation products of water ice is adequate to remove the layer. This scenario remains feasible even for particles on the scale of hundreds of microns. This finding is crucial as the sublimation of water ice continues to be the most probable mechanism for dust removal. This study partially overturns the previously held, pessimistic view regarding the possibility of dust removal via water sublimation. We demonstrate that a more precise consideration of various physical processes allows elevation of the matter of dust activity to a practical plane, necessitating a fresh quantitative analysis.
近表面水冰作为彗星尘埃活动驱动力的充足性。重新思考古老的谜团
几乎所有关于彗星尘埃活动的当代理论研究都依赖于描述近表面多孔层内热传导和升华产物的模型。气体流对结壳团块产生压力阻力,抵消了该层的微弱引力和拉伸强度。我们对 "罗塞塔 "任务数据的解读,以及对彗星活动更广泛的理解,在很大程度上取决于对这一过程的研究。我们研究了近表面多孔层的结构及其相关的气体流动阻力、拉伸强度、压力分布和其他特征在尘埃团块的潜在释放和由此产生的尘埃活动中的作用。我们采用了一个热物理模型,将该层的微观结构和辐射导热性考虑在内。我们同时考虑了克努森状态和过渡状态下的气体流动。为此,我们使用了测试粒子蒙特卡洛、直接模拟蒙特卡洛和传输概率等方法。我们的研究涵盖了尘埃粒子尺寸的广泛范围。我们评估了由亚毫米级和毫米级多孔聚集体组成的粉尘层的渗透性。我们对描述多孔粉尘层中气体扩散的各种模型进行了比较。在过渡和克努森两种情况下,我们都获得了非等温层内的压力曲线。我们讨论了我们对结构和组成的认识差距会如何影响拉伸强度估计值。我们证明,对于毫米范围内的颗粒,水冰升华产物的提升力足以移除该层。即使是数百微米的颗粒,这种情况也是可行的。这一发现至关重要,因为水冰升华仍然是最可能的除尘机制。这项研究部分推翻了之前对通过水升华除尘的可能性所持的悲观看法。我们证明,对各种物理过程进行更精确的考虑,可以将尘埃活动问题提升到实用的层面,从而有必要进行全新的定量分析。
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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