Thermodynamics of Magnesium Binding at Calcite Kink Sites and Implications for Growth inhibition

IF 4.3 3区材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-10-10 DOI:10.1021/acs.cgd.4c0099510.1021/acs.cgd.4c00995

Julie Aufort*, Blake I. Armstrong, Paolo Raiteri and Julian D. Gale,

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Abstract

The standard dissolution free energies of magnesium binding at each of the eight distinct calcite cation kinks were computed from classical molecular dynamics simulations using alchemical methods to transform magnesium into calcium at each site. The preferred calcite kink site for magnesium binding is found to correspond to one of the two symmetry inequivalent cation sites at the acute step along the kink direction that forms an obtuse angle between the end of the row and terrace (AO_a according to our notation system). Incorporation of magnesium at this site is found to inhibit growth along the step edge. However, this effect occurs not due to destabilization of the addition of the next carbonate immediately adjacent to Mg but instead by altering the thermodynamics of the subsequent cation. The binding free energy of this calcium site is reduced by more than 10 kJ/mol once magnesium has been incorporated in the step edge. Our results support and provide a mechanistic explanation for the experimental observation that acute steps are more affected by the presence of magnesium in the growth solution relative to obtuse steps.

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镁与方解石扭结点结合的热力学及其对生长抑制的影响

通过经典分子动力学模拟，计算了镁在八个不同方解石阳离子扭结处结合的标准溶解自由能，并使用炼金术方法将镁转化为钙。结果发现，镁结合的首选方解石扭结位点与两个对称性不等的阳离子位点之一相对应，这两个位点位于沿着扭结方向形成钝角的锐角台阶上（根据我们的符号系统，为 AOa）。在该位置镁的掺入会抑制阶梯边缘的生长。然而，这种效应的产生并不是由于紧邻镁的下一个碳酸盐的加入不稳定，而是由于改变了后续阳离子的热力学。一旦镁加入阶梯边缘，该钙位点的结合自由能就会降低 10 kJ/mol 以上。我们的研究结果支持并从机理上解释了实验观察结果，即相对于钝台阶，急台阶受生长溶液中镁存在的影响更大。

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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