David A. Kreplin scite author profile

Molpro is a general purpose quantum chemistry software package with a long development history. It was originally focused on accurate wavefunction calculations for small molecules but now has many additional distinctive capabilities that include, inter alia, local correlation approximations combined with explicit correlation, highly efficient implementations of single-reference correlation methods, robust and efficient multireference methods for large molecules, projection embedding, and anharmonic vibrational spectra. In addition to conventional input-file specification of calculations, Molpro calculations can now be specified and analyzed via a new graphical user interface and through a Python framework.

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Second-order MCSCF optimization revisited. I. Improved algorithms for fast and robust second-order CASSCF convergence

Kreplin

2019

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Accurate thermochemistry from explicitly correlated distinguishable cluster approximation

Kats

Kreplin

Werner

et al. 2015

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An explicitly correlated version of the distinguishable-cluster approximation is presented and extensively benchmarked. It is shown that the usual F12-type explicitly correlated approaches are applicable to distinguishable-cluster theory with single and double excitations, and the results show a significant improvement compared to coupled-cluster theory with singles and doubles for closed and open-shell systems. The resulting method can be applied in a black-box manner to systems with single- and multireference character. Most noticeably, optimized geometries are of coupled-cluster singles and doubles with perturbative triples quality or even better.

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MCSCF optimization revisited. II. Combined first- and second-order orbital optimization for large molecules

Kreplin

Knowles

Werner

2020

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A new orbital optimization for the multiconfiguration self-consistent field (MCSCF) method is presented. This method combines a second-order (SO) algorithm for the optimization of the active orbitals with the first-order Super-CI (SCI) optimization of the remaining closed-virtual rotations and is denoted as SO-SCI method. The SO-SCI method improves the convergence significantly as compared to the conventional SCI method. In combination with density fitting, the intermediates from the gradient calculation can be reused to evaluate the two-electron integrals required for the active Hessian without introducing a large computational overhead. The orbitals and configuration interaction (CI) coefficients are optimized alternately, but the CI-orbital coupling is accounted for by the Limited Memory Broyden-Fletcher-Goldfarb-Shanno (L-BFGS) quasi-Newton method. This further improves the speed of convergence. The method is applicable to large molecules. The efficiency and robustness of the presented method is demonstrated in benchmark calculations for 21 aromatic molecules as well as for various transition metal complexes with up to 826 electrons and 5154 basis functions.

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A combined first- and second-order optimization method for improving convergence of Hartree–Fock and Kohn–Sham calculations

Kreplin

Werner

2022

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In this work we investigate the optimization of Hartree-Fock (HF) orbitals with our recently proposed combined first- and second-order (SO-SCI) method, which was originally developed for multi-configuration self-consist field (MCSCF) and complete active space SCF (CASSCF) calculations. In MCSCF/CASSCF it uses a second-order optimization of the active orbitals with a Fock-based first-order treatment of the remaining closed-virtual orbital rotations. In case of the single-determinant wavefunctions, the active space is replaced by a preselected 'second-order domain', and all rotations involving orbitals in this subspace are treated at second-order. The method has been implemented for spin-restricted and spin-unrestricted Hartree-Fock (RHF, UHF), complete averaged Hartree-Fock (CAHF), as well as Kohn-Sham (KS) density functional theory (RKS, UKS). For each of these cases various choices of the second-order domain have been tested, and appropriate defaults are proposed.The performance of the method is demonstrated for several transition metal complexes. It is shown that the SO-SCI optimization provides faster and more robust convergence than the standard SCF procedure, but requires in many cases even less computation time. In difficult cases the SO-SCI method not only speeds up convergence, but also avoids convergence to saddle-points. Furthermore, it helps to find spin-symmetry broken solutions in the cases of UHF or UKS. In the case of CAHF, convergence can also be significantly improved as compared to a previous SCF implementation. This is particularly important for multi-center cases with two or more equal heavy atoms. The performance is demonstrated for various two-center complexes with different lanthanide atoms.

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David A. Kreplin

The Molpro quantum chemistry package

Second-order MCSCF optimization revisited. I. Improved algorithms for fast and robust second-order CASSCF convergence

Accurate thermochemistry from explicitly correlated distinguishable cluster approximation

MCSCF optimization revisited. II. Combined first- and second-order orbital optimization for large molecules

A combined first- and second-order optimization method for improving convergence of Hartree–Fock and Kohn–Sham calculations

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