Litcius/Paper detail

Nuclear-electronic all-particle density matrix renormalization group

Andrea Muolo, Alberto Baiardi, Robin Feldmann, Markus Reiher

2020The Journal of Chemical Physics29 citationsDOIOpen Access PDF

Abstract

We introduce the Nuclear-Electronic All-Particle Density Matrix Renormalization Group (NEAP-DMRG) method for solving the time-independent Schrödinger equation simultaneously for electrons and other quantum species. In contrast to the already existing multicomponent approaches, in this work, we construct from the outset a multi-reference trial wave function with stochastically optimized non-orthogonal Gaussian orbitals. By iterative refining of the Gaussians’ positions and widths, we obtain a compact multi-reference expansion for the multicomponent wave function. We extend the DMRG algorithm to multicomponent wave functions to take into account inter- and intra-species correlation effects. The efficient parameterization of the total wave function as a matrix product state allows NEAP-DMRG to accurately approximate the full configuration interaction energies of molecular systems with more than three nuclei and 12 particles in total, which is currently a major challenge for other multicomponent approaches. We present the NEAP-DMRG results for two few-body systems, i.e., H2 and H3+, and one larger system, namely, BH3.

Topics & Concepts

Density matrix renormalization groupWave functionMatrix product statePhysicsGaussianDensity matrixMatrix (chemical analysis)Correlation function (quantum field theory)Quantum mechanicsFunction (biology)Statistical physicsRenormalization groupProduct (mathematics)QuantumExcited stateMatrix multiplicationRenormalizationOrthogonalityIterative methodSpectrum (functional analysis)MathematicsState (computer science)Independence (probability theory)Term (time)Probability density functionGaussian processState-transition matrixSpectral densityElectronMathematical physicsGroup (periodic table)PropagatorQuantum electrodynamicsAdvanced Chemical Physics StudiesNuclear physics research studiesAdvanced Physical and Chemical Molecular Interactions