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采用标量相对论芯-价分离运动方程耦合簇方法对第一行元素的 K 边电离能进行基准计算。

Benchmark Calculations of K-Edge Ionization Energies for First-Row Elements Using Scalar-Relativistic Core-Valence-Separated Equation-of-Motion Coupled-Cluster Methods.

机构信息

Department of Chemistry , The Johns Hopkins University , Baltimore , Maryland 21218 , United States.

Department of Chemistry , Southern Methodist University , Dallas , Texas 75275 , United States.

出版信息

J Chem Theory Comput. 2019 Mar 12;15(3):1642-1651. doi: 10.1021/acs.jctc.8b01160. Epub 2019 Feb 15.

DOI:10.1021/acs.jctc.8b01160
PMID:30702889
Abstract

Benchmark scalar-relativistic core-valence-separated (CVS) equation-of-motion coupled-cluster ionization potential (EOMIP-CC) calculations of 21 K-edge ionization energies of C, O, N, and F in 14 molecules are reported. The CVS-EOMIP-CC methods are shown to be numerically more stable and more accurate than the parent EOMIP-CC methods, even when the calculations using the latter can be tightly converged. The superior performance of the CVS scheme is attributed to the exclusion of spurious couplings between core-ionized states and valence continuum states. Systematic improvement of computed K-edge ionization energies within the CVS-EOMIP-CC hierarchy, including the CC singles and doubles (CCSD) method, the CC singles, doubles, and triples (CCSDT) method, and the CC singles, doubles, triples, and quadruples (CCSDTQ) method, is demonstrated, with CCSDTQ yielding essentially quantitative results. Maximum absolute deviations between computed and experimental results amount to 2.54 eV for CCSD/cc-pCVQZ, 0.54 eV for CCSDT/cc-pCVQZ, and 0.23 eV for CCSDT/cc-pCVQZ augmented with quadruples contributions using the cc-pVTZ basis sets. The corresponding standard deviations are 1.91 eV for CCSD/cc-pCVQZ, 0.18 eV for CCSDT/cc-pCVQZ, and 0.10 eV for CCSDT/cc-pCVQZ augmented with quadruples contributions using the cc-pVTZ basis sets. Finally, CVS-EOMIP-CCSDT/cc-pCVTZ calculations of core ionization energies in CHCN and CHNC are reported, and experimental reinvestigation of carbon 1s ionization energies in CHCN is suggested.

摘要

报道了 14 个分子中 C、O、N 和 F 的 21 个 K 边电离能的基准标量相对论核壳分离(CVS)方程运动耦合簇电离电位(EOMIP-CC)计算。与母体 EOMIP-CC 方法相比,CVS-EOMIP-CC 方法在数值上更稳定,更准确,即使使用后者可以紧密收敛。CVS 方案的优越性能归因于排除了芯电离态与价连续态之间的虚假耦合。在 CVS-EOMIP-CC 层次结构内,包括 CC 单和双(CCSD)方法、CC 单、双和三(CCSDT)方法以及 CC 单、双、三、四(CCSDTQ)方法,计算的 K 边电离能得到了系统的改善,CCSDTQ 产生了基本定量的结果。计算结果与实验结果之间的最大绝对偏差为 CCSD/cc-pCVQZ 的 2.54 eV,CCSDT/cc-pCVQZ 的 0.54 eV,以及使用 cc-pVTZ 基组的 CCSDT/cc-pCVQZ 加上四倍贡献的 0.23 eV。相应的标准偏差为 CCSD/cc-pCVQZ 的 1.91 eV,CCSDT/cc-pCVQZ 的 0.18 eV,以及使用 cc-pVTZ 基组的 CCSDT/cc-pCVQZ 加上四倍贡献的 0.10 eV。最后,报道了 CHCN 和 CHNC 中芯电离能的 CVS-EOMIP-CCSDT/cc-pCVTZ 计算,并建议对 CHCN 中碳 1s 电离能进行实验再研究。

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