Dissociation line and driving force for nucleation of the nitrogen hydrate from computer simulation. II. Effect of multiple occupancy

arXiv - PHYS - Soft Condensed Matter Pub Date : 2024-08-06 DOI:arxiv-2408.03257

Miguel J. Torrejón, Jesús Algaba, Felipe J. Blas

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Abstract

In this work, we determine the dissociation line of the nitrogen (N$_{2}$) hydrate by computer simulation using the TIP4P/Ice model for water and the TraPPE force field for N$_{2}$. This work is the natural extension of our previous paper in which the dissociation temperature of the N$_2$ hydrate has been obtained at $500$, $1000$, and $1500\,\text{bar}$ [\emph{J. Chem. Phys.} \textbf{159}, 224707 (2023)] using the solubility method and assuming single occupancy. We extend our previous study and determine the dissociation temperature of the N$_2$ hydrate at different pressures, from $500$ to $4500\,\text{bar}$, taking into account single and double occupancy of the N$_{2}$ molecules in the hydrate structure. We calculate the solubility of N$_2$ in the aqueous solution, as a function of temperature, when it is in contact with a N$_{2}$-rich liquid phase and when in contact with the hydrate phase with single and double occupancy via planar interfaces. Both curves intersect at a certain temperature that determines the dissociation temperature at a given pressure. We observe a negligible effect of the occupancy on the dissociation temperature. Our findings are in very good agreement with the experimental data taken from the literature. We have also obtained the driving force for nucleation of the hydrate as a function of the temperature and occupancy at several pressures. As in the case of the dissociation line, the effect of the occupancy on the driving force for nucleation is negligible. To the best of our knowledge, this is the first time that the effect of the occupancy on the driving force for nucleation of a hydrate that exhibits sII crystallographic structure is studied from computer simulation.

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计算机模拟氮水合物的离解线和成核驱动力。II.多重占据的影响

在这项工作中，我们使用水的 TIP4P/Ice 模型和 N$_{2}$ 的 TraPPE 力场，通过计算机模拟确定了氮（N$_{2}$）水合物的解离线。这项工作是我们上一篇论文的自然延伸，在上一篇论文中，我们使用溶解度方法并假设单占位，得到了 N$_2$ 水合物在 $500$、$1000$ 和 $1500\text{bar}$[\emph{J. Chem. Phys.}\textbf{159}, 224707 (2023)]时的解离温度。我们扩展了之前的研究，考虑到水合物结构中 N$_{2}$ 分子的单占有和双占有，确定了 N$_2$ 水合物在 500 美元到 4500 美元不同压力下的解离温度。当水溶液与富含 N$_{2}$ 的液相接触时，以及当水合物通过平面界面与单双占位的水合物相接触时，我们计算了 N$_2$ 在水溶液中的溶解度与温度的函数关系。两条曲线在某一温度相交，该温度决定了给定压力下的解离温度。我们观察到占位对解离温度的影响微乎其微。我们的发现与文献中的实验数据非常吻合。我们还获得了水合物成核的驱动力，它是若干压力下温度和占位率的函数。与解离线的情况一样，占位对成核驱动力的影响可以忽略不计。据我们所知，这是首次通过计算机模拟研究占位率对呈现 sII 晶体结构的水合物成核驱动力的影响。

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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arXiv - PHYS - Soft Condensed Matter

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