石英/电解质界面处的pKa值。

pKa at Quartz/Electrolyte Interfaces.

作者信息

Pfeiffer-Laplaud Morgane, Gaigeot Marie-Pierre, Sulpizi Marialore

机构信息

LAMBE CNRS UMR8587, Université d'Evry val d'Essonne , Blvd F. Mitterrand, Bât Maupertuis, 91025 Evry, France.

Department of Physics, Johannes Gutenberg Universität , Staudingerweg 7, 55099 Mainz, Germany.

出版信息

J Phys Chem Lett. 2016 Aug 18;7(16):3229-34. doi: 10.1021/acs.jpclett.6b01422. Epub 2016 Aug 4.

DOI:10.1021/acs.jpclett.6b01422

PMID:27483195

Abstract

Acidity of silanol sites at the crystalline quartz/aqueous electrolyte (NaCl, NaI, KCl) interfaces are calculated from ab initio molecular dynamics simulations. pKa's are found to follow a combination of the cationic and anionic Hofmeister series in the order pKa(neat solution) < pKa(NaCl) < pKa(NaI) < pKa(KCl), in agreement with experimental measurements. Rationalization of this ranking is achieved in terms of the microscopic local solvation of the protonated silanols and their conjugated bases, the silanolates SiO(-). The change in the pKa is the result of both water destructuring by alkali halides, as well as of the specific cation/SiO(-) interaction, depending on the electrolyte. Molecular modeling at the atomistic level is required to achieve such comprehension, with ab initio molecular dynamics being able to model complex inhomogeneous charged interfaces and the associated interfacial chemical reactivity.

摘要

通过从头算分子动力学模拟计算了晶体石英/水性电解质（NaCl、NaI、KCl）界面处硅醇位点的酸度。发现pKa遵循阳离子和阴离子霍夫迈斯特序列的组合，顺序为pKa（纯溶液）<pKa（NaCl）<pKa（NaI）<pKa（KCl），这与实验测量结果一致。根据质子化硅醇及其共轭碱硅醇盐SiO(-)的微观局部溶剂化作用，对这种排序进行了合理化解释。pKa的变化是碱金属卤化物导致水结构破坏以及特定阳离子/SiO(-)相互作用的结果，具体取决于电解质。需要进行原子水平的分子建模才能达到这样的理解，从头算分子动力学能够对复杂的非均匀带电界面及其相关的界面化学反应性进行建模。

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石英/电解质界面处的pKa值。

pKa at Quartz/Electrolyte Interfaces.

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