基于Cholesky分解的多参考体系色散能高效计算：在激发态相互作用中的应用

Efficient Calculation of the Dispersion Energy for Multireference Systems with Cholesky Decomposition: Application to Excited-State Interactions.

作者信息

Hapka Michał, Krzemińska Agnieszka, Modrzejewski Marcin, Przybytek Michał, Pernal Katarzyna

机构信息

Faculty of Chemistry, University of Warsaw, ul. L. Pasteura 1, 02-093 Warsaw, Poland.

Institute of Physics, Lodz University of Technology, ul. Wolczanska 217/221, 93-005 Lodz, Poland.

出版信息

J Phys Chem Lett. 2023 Aug 3;14(30):6895-6903. doi: 10.1021/acs.jpclett.3c01568. Epub 2023 Jul 26.

DOI:10.1021/acs.jpclett.3c01568

PMID:37494637

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10405273/

Abstract

Accurate and efficient prediction of dispersion interactions in excited-state complexes poses a challenge due to the complex nature of electron correlation effects that need to be simultaneously considered. We propose an algorithm for computing the dispersion energy in nondegenerate ground- or excited-state complexes with arbitrary spin. The algorithm scales with the fifth power of the system size due to employing Cholesky decomposition of Coulomb integrals and a recently developed recursive formula for density response functions of the monomers. As a numerical illustration, we apply the new algorithm in the framework of multiconfigurational symmetry adapted perturbation theory, SAPT(MC), to study interactions in dimers with localized excitons. The SAPT(MC) analysis reveals that the dispersion energy may be the main force stabilizing excited-state dimers.

摘要

由于需要同时考虑电子相关效应的复杂性质，准确高效地预测激发态复合物中的色散相互作用面临挑战。我们提出了一种用于计算具有任意自旋的非简并基态或激发态复合物中色散能的算法。由于采用了库仑积分的Cholesky分解以及最近开发的单体密度响应函数的递归公式，该算法与系统大小的五次方成正比。作为数值示例，我们在多构型对称适配微扰理论（SAPT(MC)）框架下应用新算法来研究具有局域激子的二聚体中的相互作用。SAPT(MC)分析表明，色散能可能是稳定激发态二聚体的主要作用力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b291/10405273/2a1dd1f8f2f1/jz3c01568_0001.jpg

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基于Cholesky分解的多参考体系色散能高效计算：在激发态相互作用中的应用

Efficient Calculation of the Dispersion Energy for Multireference Systems with Cholesky Decomposition: Application to Excited-State Interactions.

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