QUEST\#4X: an extension of QUEST\#4 for benchmarking multireference wavefunction methods

arXiv - PHYS - Chemical Physics Pub Date : 2024-08-30 DOI:arxiv-2409.00302

Yangyang Song, Ning Zhang, Yibo Lei, Yang Guo, Wenjian Liu

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Abstract

Given a number of datasets for evaluating the performance of single reference methods for the low-lying excited states of closed-shell molecules, a comprehensive dataset for assessing the performance of multireference methods for the low-lying excited states of open-shell systems is still lacking. For this reason, we propose an extension (QUEST\#4X) of the radial subset of QUEST\#4 [J. Chem. Theory Comput. 2020, 16, 3720] to cover 110 doublet and 39 quartet excited states. Near-exact results obtained by iCIPT2 (iterative configuration interaction with selection and second-order perturbation correction) are taken as benchmark to calibrate SDSCI (static-dynamic-static configuration interaction) and SDSPT2 (static-dynamic-static second-order perturbation theory), which are minimal MRCI and CI-like perturbation theory, respectively. It is found that SDSCI is very close in accuracy to ic-MRCISD (internally contracted multireference configuration interaction with singles and doubles), although its computational cost is just that of one iteration of the latter. Unlike most variants of MRPT2, SDSPT2 treats single and multiple states in the same way, and performs similarly as MS-NEVPT2 (multi-state n-electron valence second-order perturbation theory). These findings put the SDS family of methods (SDSPT2, SDSCI, and iCIPT2, etc.) on a firm basis.

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QUEST\#4X：QUEST\#4的扩展，用于多参考波函数方法的基准测试

鉴于有许多用于评估闭壳分子低洼激发态的单参比方法性能的数据集，目前仍然缺乏用于评估开壳系统低洼激发态的多参比方法性能的综合数据集。为此，我们提出了扩展（QUEST/#4X）QUEST/#4 的径向子集[J. Chem. Theory Comput.以 iCIPT2（带选择和二阶扰动校正的迭代配置相互作用）得到的接近精确的结果为基准，校准了 SDSCI（静态-动态-静态配置相互作用）和 SDSPT2（静态-动态-静态二阶扰动理论），它们分别是最小 MRCI 和类 CI 扰动理论。研究发现，SDSCI 在精度上非常接近 ic-MRCISD（内部收缩多参量构型单倍和双倍相互作用），尽管其计算成本仅为后者一次迭代的成本。与 MRPT2 的大多数变体不同，SDSPT2 以相同的方式处理单态和多态，其性能与 MS-NEVPT2（多态电子价二阶扰动理论）类似。这些发现为 SDS 系列方法（SDSPT2、SDSCI 和 iCIPT2 等）奠定了坚实的基础。

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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arXiv - PHYS - Chemical Physics

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