Quantum Mechanical Rate Coefficient of Formation of HD Molecule at Ultracold Temperatures: Its Importance in Interstellar Cooling

Journal of Atomic, Molecular, Condensate and Nano Physics Pub Date : 2015-12-28 DOI:10.26713/JAMCNP.V2I3.338

Rangappa Santosh, S. Ghosal

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引用次数: 1

Abstract

Molecular hydrogen and its isotope HD acted as one of the most important interstellar coolants in the primordial gas medium. In this paper, we present accurate time-independent quantum mechanical (TIQM) rate coefficients of formation of ultracold HD molecules by \({\rm D} +{\rm H}_2(v,j)\to {\rm HD}(v', j')+{\rm H}\) reaction at very low collision energy. State resolved integral cross sections between different rotational \((j)\) and vibrational \((v)\) levels and corresponding Boltzmann-averaged thermal rate coefficients are computed between temperature \(\rm T = 10^{-8}K\)-\(\rm 10K\). We found the exponential decrease of the rate coefficients with reducing temperature following Arrhenius' empirical equation is not valid at ultracold temperature limit. At lower temperatures, the rate coefficients become independent of temperature (constant) and Wigner's threshold laws are obeyed. Since cooling of the primordial gases lead to the formation of the first structures of the universe, inclusion of the accurate low-temperature rate coefficients will lead to improved modeling for the evolution of the early universe.

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超低温下HD分子形成的量子力学速率系数及其在星际冷却中的重要性

分子氢及其同位素HD是原始气体介质中最重要的星际冷却剂之一。本文给出了超低碰撞能量下\({\rm D} +{\rm H}_2(v,j)\to {\rm HD}(v', j')+{\rm H}\)反应形成超冷HD分子的精确时无关量子力学(TIQM)速率系数。在温度\(\rm T = 10^{-8}K\) - \(\rm 10K\)之间，计算了不同旋转\((j)\)和振动\((v)\)能级之间的状态分解积分截面以及相应的玻尔兹曼平均热率系数。结果表明，在超冷极限下，速率系数随温度降低呈指数递减的Arrhenius经验方程是不成立的。在较低的温度下，速率系数与温度(常数)无关，并服从维格纳阈值定律。由于原始气体的冷却导致了宇宙第一个结构的形成，因此包含精确的低温速率系数将导致对早期宇宙演化的改进建模。

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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Journal of Atomic, Molecular, Condensate and Nano Physics

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