Related papers: Striking the Right Balance of Encoding Electron Correlation in the Hamiltonian and the Wavefunction Ansatz

Striking the Right Balance of Encoding Electron Correlation in the Hamiltonian and the Wavefunction Ansatz

URL: http://arxiv.org/abs/2404.19172v1
Date: Tue, 30 Apr 2024 00:34:34 GMT
Title: Striking the Right Balance of Encoding Electron Correlation in the Hamiltonian and the Wavefunction Ansatz
Authors: Kalman Szenes, Maximilian Moerchen, Paul Fischill, Markus Reiher,
Abstract summary: Multi-configurational electronic structure theory delivers the most versatile approximations to many-electron wavefunctions. We argue in favor of simple electrons-only correlator expressions that may allow one to define transcorrelated models.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Multi-configurational electronic structure theory delivers the most versatile approximations to many-electron wavefunctions, flexible enough to deal with all sorts of transformations, ranging from electronic excitations, to open-shell molecules and chemical reactions. Multi-configurational models are therefore essential to establish universally applicable, predictive ab initio methods for chemistry. Here, we present a discussion of explicit correlation approaches which address the nagging problem of dealing with static and dynamic electron correlation in multi-configurational active-space approaches. We review the latest developments and then point to their key obstacles. Our discussion is supported by new data obtained with tensor network methods. We argue in favor of simple electrons-only correlator expressions that may allow one to define transcorrelated models in which the correlator does not bear a dependence on molecular structure.

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