Excited State Structure and Minimum Energy Conical Intersection Optimization Using DFT/MRCI

07 October 2024, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

The combined density functional theory and multi-reference configuration interaction (DFT/MRCI) method is a semi-empirical selected-CI electronic structure approach that is both computationally efficient and of predictive accuracy for the calculation of electronic excited states and simulation of electronic spectroscopies. However, given that the reference space is generated via selected-CI, a challenge arises in the construction of smooth potential energy surfaces. To address this issue, we treat the local discontinuities as noise within the Gaussian Progress Regression framework and learn the surfaces by explicitly optimizing a white-noise kernel. The characteristic polynomial coefficient surfaces, which are smooth functions of nuclear coordinates even at conical intersections, are learned in place of the adiabatic energy surfaces and are used to optimize the DFT/MRCI(2) minimum energy conical intersection geometries for representative intersection motifs in the molecules ethylene, butadiene, and fulvene. One consequence of explicitly treating the noise in the surfaces is that the energy difference cannot be made arbitrarily small at points of nominal intersection. Despite the limitations, however, we find the structures as well as the branching spaces to compare well with \textit{ab initio} MRCI and conclude that this approach is a viable method to learn a smooth representation of DFT/MRCI(2) surfaces.

Keywords

Conical Intersection
Structure Optimization
DFT/MRCI

Supplementary materials

Title
Description
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Title
Supporting Information for the Excited State Structure and Minimum Energy Conical Intersection Optimization Using DFT/MRCI
Description
Supporting information for "Excited State Structure and Minimum Energy Conical Intersection Optimization Using DFT/MRCI". It includes supplementary figures and tables that are referenced in the main text, such as S1 minimum optimization and details of machine learning parameters and details for the electronic structure methods used
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Title
Optimized DFT/MRCI(2) MECI
Description
Contains all the optimized DFT/MRCI(2) MECIS for ethylene, butadiene and fulvene over the 50 surrogates with different LHS generated training data in .xyz file
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Title
Optimized ab initio MRCI MECIs
Description
Contains all the optimized analytical MR-CIS and MR-CISD MECIs for ethylene, butadiene and fulvene in .xyz files.
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