论高斯基集在核心相关特性方面的特殊化

Robbie T. Ireland, Laura K. McKemmish
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引用次数: 0

摘要

尽管大多数量子化学基础集是为准确模拟价态化学而设计的,但这些通用基础集仍被广泛用于模拟依赖于核的性质。内核专用基础集的设计具有特定的特征,可以准确地表示内核区域的行为。这种设计通常包含具有较高指数的高斯基元,以有效捕捉核心行为,并对基函数进行一定的去收缩,以提供描述核心电子波函数的灵活性。s$- 和 p$- 基函数的最高高斯指数和收缩程度有效地描述了这些设计方面。在这项研究中,我们将通用基集的设计和性能与几种专门针对三个核心相关特性设计的文献基集进行了比较:J耦合常数、超精细耦合常数和磁屏蔽常数(用于计算化学位移)。我们的研究结果一致表明,与常用的 6-31G** 基集相比,采用内核专用基集可显著减少误差,但计算成本往往略有增加。值得注意的是,为了快速计算 J 耦合、超细耦合和磁屏蔽常数,我们建议分别使用 pcJ-1、EPR-II 和 pcSseg-1 基集。为了获得更高的精度,建议使用 pcJ-2、EPR-III 和 pcSseg-2 基础集。
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On the Specialisation of Gaussian Basis Sets for Core-Dependent Properties
Despite the fact that most quantum chemistry basis sets are designed for accurately modelling valence chemistry, these general-purpose basis sets continue to be widely used to model core-dependent properties. Core-specialised basis sets are designed with specific features to accurately represent the behaviour of the core region. This design typically incorporates Gaussian primitives with higher exponents to capture core behaviour effectively, as well as some decontraction of basis functions to provide flexibility in describing the core electronic wave function. The highest Gaussian exponent and the degree of contraction for both $s$- and $p$-basis functions effectively characterise these design aspects. In this study, we compare the design and performance of general-purpose basis sets against several literature basis sets specifically designed for three core-dependent properties: J coupling constants, hyperfine coupling constants, and magnetic shielding constants (used for calculating chemical shifts). Our findings consistently demonstrate a significant reduction in error when employing core-specialised basis sets, often at a marginal increase in computational cost compared to the popular 6-31G** basis set. Notably, for expedient calculations of J coupling, hyperfine coupling and magnetic shielding constants, we recommend the use of the pcJ-1, EPR-II, and pcSseg-1, basis sets respectively. For higher accuracy, the pcJ-2, EPR-III, and pcSseg-2 basis sets are recommended.
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