Litcius/Paper detail

Self-Consistent-Field Method for Correlated Many-Electron Systems with an Entropic Cumulant Energy

Jian Wang, Evert Jan Baerends

2022Physical Review Letters42 citationsDOIOpen Access PDF

Abstract

A self-consistent field method is presented within density matrix functional theory. The computational cost for a correlated many-electron calculation is reduced to that of the self-consistent-field Hartree-Fock method, while the accuracy still reaches that of sophisticated configuration interaction based methods. In this method, the two-electron cumulant energy is measured with an information entropy associated with the Fermi-Dirac distribution of the occupation numbers. An eigenvalue equation for the orbitals is obtained, with the eigenvalues (orbital energies) connected to the occupation numbers through the Fermi-Dirac distribution. The occupation numbers for the strongly occupied orbitals are very close to the natural orbital occupation numbers from wave function methods. It covers in a single scheme the nondynamical correlation in weak or breaking bonds as well as the dynamical correlation at all distances. The method is well suited to large-scale potential energy surface calculation and molecular dynamics simulation.

Topics & Concepts

Eigenvalues and eigenvectorsPhysicsCumulantStatistical physicsAtomic orbitalEntropy (arrow of time)Wave functionQuantum mechanicsFunction (biology)Energy (signal processing)Field (mathematics)Principle of maximum entropyDensity matrixMolecular dynamicsMatrix (chemical analysis)Energy functionalCorrelation function (quantum field theory)Potential energyConfiguration entropyDistribution (mathematics)Molecular orbitalProbability density functionDensity functional theoryRandom matrixWavenumberDistribution functionSurface (topology)Classical mechanicsAdvanced Chemical Physics StudiesAdvanced Physical and Chemical Molecular InteractionsMagnetism in coordination complexes