Reduced Scaling Correlated Natural Transition Orbitals for Multilevel Coupled Cluster Calculations

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-10-24 DOI:10.1021/acs.jpca.4c0627110.1021/acs.jpca.4c06271

Sarai Dery Folkestad*, and , Henrik Koch,

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Abstract

Multilevel coupled cluster theory offers reduced scaling computation of intensive properties in systems that are too large for standard coupled cluster calculations. A significant benefit of the multilevel coupled cluster framework is the possibility of calculating intensive properties that are not tightly localized if an appropriate set of active orbitals is used. Correlated natural transition orbitals (CNTOs) are tailored to describe excitation processes. For multilevel coupled cluster singles and doubles (MLCCSD) and singles and perturbative doubles (MLCC2) calculations, the construction of CNTOs generally becomes the computational bottleneck. Here, we demonstrate how CNTOs can be obtained with $O (N^{3})$ operations, eliminating the $O (N^{5})$ -scaling steps involved in the original approach. This reduction in scaling moves the bottleneck of MLCC2 and MLCCSD calculations from the active orbital space preparation to the MLCC2 and MLCCSD equations with $O (N^{4})$ -scaling.

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用于多级耦合簇计算的缩放相关自然过渡轨道

多层次耦合簇理论可在系统过于庞大而无法进行标准耦合簇计算的情况下，减少对密集特性的缩放计算。多级耦合簇框架的一个显著优点是，如果使用一组适当的活动轨道，就有可能计算出非紧密局部的密集特性。相关自然过渡轨道（CNTO）是为描述激发过程而定制的。对于多级耦合簇单倍和双倍（MLCCSD）以及单倍和微扰双倍（MLCC2）计算，CNTO 的构建通常成为计算瓶颈。在此，我们展示了如何通过 O(N3) 次运算获得 CNTO，从而消除了原始方法中涉及的 O(N5) 次缩放步骤。这种缩放的减少将 MLCC2 和 MLCCSD 计算的瓶颈从活动轨道空间准备转移到了 O(N4)- 缩放的 MLCC2 和 MLCCSD 方程。

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