A Filon-like integration strategy for calculating exact exchange in periodic boundary conditions: a plane-wave DFT implementation

Eric J Bylaska, Kevin Waters, Eric D Hermes, Judit Zádor, Kevin M Rosso
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引用次数: 4

Abstract

An efficient and accurate approach for calculating exact exchange and other two-electron integrals has been developed for periodic electronic structure methods. Traditional approaches used for integrating over the Brillouin zone in band structure calculations, e.g. trapezoidal or Monkhorst-Pack, are not accurate enough for two-electron integrals. This is because their integrands contain multiple singularities over the double integration of the Brillouin zone, which with simple integration methods lead to very inaccurate results. A common approach to this problem has been to replace the Coulomb interaction with a screened Coulomb interaction that removes singularities from the integrands in the two-electron integrals, albeit at the inelegance of having to introduce a screening factor which must precomputed or guessed. Instead of introducing screened Coulomb interactions in an ad hoc way, the method developed in this work derives an effective screened potential using a Filon-like integration approach that is based only on the lattice parameters. This approach overcomes the limitations of traditionally defined screened Coulomb interactions for calculating two-electron integrals, and makes chemistry many-body calculations tractable in periodic boundary conditions. This method has been applied to several systems for which conventional DFT methods do not work well, including the reaction pathways for the addition of H2 to phenol and Au\(_{20}^{-}\) nanoparticle, and the electron transfer of a charge trapped state in the Fe(II) containing mica, annite.

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计算周期边界条件下精确交换的类filon积分策略:平面波DFT实现
为周期电子结构方法提供了一种计算精确交换积分和其他双电子积分的有效而精确的方法。在带结构计算中用于布里渊区积分的传统方法,例如梯形或Monkhorst-Pack,对于双电子积分不够精确。这是因为它们的积分在布里渊区的二重积分上包含多个奇异点,用简单的积分方法会导致非常不准确的结果。解决这个问题的一种常用方法是用屏蔽的库仑相互作用取代库仑相互作用,这种相互作用消除了双电子积分中积分的奇异性,尽管不得不引入必须预先计算或猜测的屏蔽因子是不优雅的。这项工作中开发的方法不是以特别的方式引入筛选库仑相互作用,而是使用仅基于晶格参数的类菲龙积分方法推导出有效的筛选势。这种方法克服了传统定义的筛选库仑相互作用计算双电子积分的局限性,使化学多体计算在周期性边界条件下变得容易。该方法已应用于几种传统DFT方法不能很好地工作的系统,包括将H2添加到苯酚和Au \(_{20}^{-}\)纳米粒子的反应途径,以及在含云母,苯胺的Fe(II)中电荷捕获态的电子转移。
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期刊介绍: Journal of Materials Science: Materials Theory publishes all areas of theoretical materials science and related computational methods. The scope covers mechanical, physical and chemical problems in metals and alloys, ceramics, polymers, functional and biological materials at all scales and addresses the structure, synthesis and properties of materials. Proposing novel theoretical concepts, models, and/or mathematical and computational formalisms to advance state-of-the-art technology is critical for submission to the Journal of Materials Science: Materials Theory. The journal highly encourages contributions focusing on data-driven research, materials informatics, and the integration of theory and data analysis as new ways to predict, design, and conceptualize materials behavior.
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