Advancing Non-Atom-Centered Basis Methods for More Accurate Interaction Energies: Benchmarks and Large-Scale Applications.

IF 2.7 2区 化学 Q3 CHEMISTRY, PHYSICAL
Balázs D Lőrincz, Péter R Nagy
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引用次数: 0

Abstract

Recent advances in local electron correlation approaches have enabled the relatively routine access to CCSD(T) [that is, coupled cluster (CC) with single, double, and perturbative triple excitations] computations for molecules of a hundred or more atoms. Here, approaching their complete basis set (CBS) limit becomes more challenging due to extensive basis set superposition errors, often necessitating the use of large atomic orbital (AO) basis sets with diffuse functions. Here, we study a potential remedy in the form of non-atom-centered or floating orbitals (FOs). FOs are still rarely employed even for small molecules due to the practical complication of defining their position, number, exponents, etc. The most frequently used FO method thus simply places a single FO center with a large number of FOs toward the middle of noncovalent dimers; however, a single FO center for larger complexes can soon become insufficient. A recent alternative uses a grid of FO centers around the monomers with a single s function per center, which is currently applicable only for H, C, N, and O atoms. Here, we build on the above advantages and mitigate some drawbacks of previous FO approaches by using a layer of FO centers and 4-9 FOs/center for each monomer. Thus, a double layer of FOs is placed between the interacting subsystems. When extending the double-ζ AO basis with this double layer of FOs, the quality of conventional augmented double-ζ or conventional triple-ζ AO bases can be reached or surpassed with less orbitals, leading to few tenths of a kcal/mol basis set errors for medium-sized dimers. This good performance extends to larger molecules (shown here up to 72 atoms), as efficient local natural orbital (LNO) CCSD(T) computations with only double-ζ AO and 4 FOs/center FO bases match our LNO-CCSD(T)/CBS reference within ca. 0.1 kcal/mol. These developments introduce FO methods to the accurate modeling of large molecular complexes without limitations to atom types by further accelerating efficient correlation calculations, like LNO-CCSD(T).

推进非原子中心基础方法以获得更精确的相互作用能:基准和大规模应用。
局部电子相关方法的最新进展使我们能够对一百个或更多原子的分子进行相对常规的 CCSD(T) [即具有单激发、双激发和扰动三激发的耦合簇(CC)]计算。在这里,由于广泛的基集叠加误差,接近其完整基集(CBS)极限变得更具挑战性,往往需要使用具有扩散函数的大型原子轨道(AO)基集。在此,我们研究了非原子中心或浮动轨道(FOs)形式的潜在补救措施。由于定义浮动轨道的位置、数量、指数等的实际复杂性,即使是小分子也很少使用浮动轨道。因此,最常用的 FO 方法只是在非共价二聚体中间放置一个带有大量 FO 的单个 FO 中心;然而,对于较大的复合物来说,单个 FO 中心很快就不够用了。最近的一种替代方法是在单体周围使用网格状的 FO 中心,每个中心只有一个 s 功能,目前只适用于 H、C、N 和 O 原子。在此,我们在上述优点的基础上,对每个单体使用一层 FO 中心和 4-9 个 FO/中心,以减轻以往 FO 方法的一些缺点。这样,在相互作用的子系统之间就形成了双层 FO。当用这双层 FO 扩展双ζ AO 基础时,传统的增强双ζ或传统的三ζ AO 基础的质量可以达到或超过,只需较少的轨道,从而使中等大小的二聚体的基础集误差仅为万分之一千卡/摩尔。这种良好的性能扩展到更大的分子(此处显示多达 72 个原子),因为仅使用双ζ AO 和 4 FOs/center FO 基底的高效局部自然轨道(LNO)CCSD(T) 计算与我们的 LNO-CCSD(T)/CBS 参考相匹配,误差在约 0.1 kcal/mol 范围内。这些进展通过进一步加速高效相关计算(如 LNO-CCSD(T)),将 FO 方法引入到大型分子复合物的精确建模中,而不受原子类型的限制。
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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来源期刊
The Journal of Physical Chemistry A
The Journal of Physical Chemistry A 化学-物理:原子、分子和化学物理
CiteScore
5.20
自引率
10.30%
发文量
922
审稿时长
1.3 months
期刊介绍: The Journal of Physical Chemistry A is devoted to reporting new and original experimental and theoretical basic research of interest to physical chemists, biophysical chemists, and chemical physicists.
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