AI Article Synopsis
- A new implementation of relativistic coupled-cluster methods using Cholesky decomposition is presented, allowing for efficient calculations in medium-sized molecules while avoiding complex integral constructions.
- This method utilizes an exact two-component Hamiltonian enhanced with atomic-mean-field spin-orbit integrals, extending its applicability to larger systems.
- Benchmark tests on uranium-containing molecules indicate that a Cholesky threshold of 10 is adequate for achieving chemical accuracy in calculations, exemplified by energy assessments of uranium hexafluoride and solvated uranyl ion.
Article Abstract
A Cholesky decomposition (CD)-based implementation of relativistic two-component coupled-cluster (CC) and equation-of-motion CC (EOM-CC) methods using an exact two-component Hamiltonian augmented with atomic-mean-field spin-orbit integrals (the X2CAMF scheme) is reported. The present CD-based implementation of X2CAMF-CC and EOM-CC methods employs atomic-orbital-based algorithms to avoid the construction of two-electron integrals and intermediates involving three and four virtual indices. Our CD-based implementation extends the applicability of X2CAMF-CC and EOM-CC methods to medium-sized molecules with the possibility to correlate around 1000 spinors. Benchmark calculations for uranium-containing small molecules were performed to assess the dependence of the CC results on the Cholesky threshold. A Cholesky threshold of 10 is shown to be sufficient to maintain chemical accuracy. Example calculations to illustrate the capability of the CD-based relativistic CC methods are reported for the bond-dissociation energy of the uranium hexafluoride molecule, UF, with up to quadruple-ζ basis sets, and the lowest excitation energy in the solvated uranyl ion [UO(HO)].
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| http://dx.doi.org/10.1021/acs.jctc.3c01236 | DOI Listing |
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Article Synopsis
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