Effect of pressure on the carbon dioxide hydrate-water interfacial free energy along its dissociation line

arXiv - PHYS - Soft Condensed Matter Pub Date : 2024-09-12 DOI:arxiv-2409.07844

Cristóbal Romero-Guzmán, Iván M. Zerón, Jesús Algaba, Bruno Mendiboure, José Manuel Míguez, Felipe J. Blas

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Abstract

We investigate the effect of pressure on the carbon dioxide (CO$_{2}$) hydrate-water interfacial free energy along its dissociation line using advanced computer simulation techniques. In previous works, we have determined the interfacial energy of the hydrate at $400 \,\text{bar}$ using the TIP4P/ice and TraPPE molecular models for water and CO$_{2}$, respectively, in combination with two different extensions of the Mold Integration technique [J. Chem. Phys. 141, 134709 (2014)]. Results obtained from computer simulation, $29(2)$ and $30(2)\,\text{mJ/m}^{2}$, are found to be in excellent agreement with the only two measurements that exist in the literature, $28(6)\,\text{mJ/m}^{2}$ determined by Uchida et al. [J. Phys. Chem. B 106, 8202 (2002)] and $30(3)\,\text{mJ/m}^{2}$ by Anderson et al. [J. Phys. Chem. B 107, 3507 (2002)]. Since the experiments do not allow to obtain the variation of the interfacial energy along the dissociation line of the hydrate, we extend our previous studies to quantify the effect of pressure on the interfacial energy at different pressures. Our results suggest that there exists a correlation between the interfacial free energy values and the pressure, i.e., it decreases with the pressure between $100$ and $1000\,\text{bar}$. We expect that the combination of reliable molecular models and advanced simulation techniques could help to improve our knowledge of the thermodynamic parameters that control the interfacial free energy of hydrates from a molecular perspective.

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压力对二氧化碳水合物-水界面自由能解离线的影响

我们利用先进的计算机模拟技术研究了压力对二氧化碳（CO$_{2}$）水合物-水界面自由能的影响。在之前的工作中，我们分别使用水和 CO$_{2}$ 的 TIP4P/ice 和 TraPPE 分子模型，结合模态积分技术的两种不同扩展，测定了水合物在 400 美元时的界面能[J.Chem. Phys. 141, 134709 (2014)]。计算机模拟得到的 29(2)$ 和 30(2)\text{mJ/m}^{2}$ 结果与文献中仅有的两个测量值，即 Uchida 等人测定的 28(6)\text{mJ/m}^{2}$ 非常吻合[J. Physical Chem B. 2, 134709 (2014)]。[J. Phys. Chem. B 106,8202 (2002)] 和 Anderson 等人 [J. Phys. Chem. B107, 3507 (2002)] 测得的 $30(3)\,text{mJ/m}^{2}$。由于实验无法获得界面能沿水合物解离线的变化，我们扩展了先前的研究，以量化压力对不同压力下界面能的影响。我们的研究结果表明，界面自由能值与压力之间存在相关性，即在 100 美元到 1000 美元之间，界面自由能随压力的增加而减小。我们希望将可靠的分子模型与先进的模拟技术相结合，有助于从分子的角度提高我们对控制水合物界面自由能的热力学参数的认识。

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