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A new form of transcorrelated Hamiltonian inspired by range-separated DFT

Emmanuel Giner

2021The Journal of Chemical Physics20 citationsDOIOpen Access PDF

Abstract

The present work introduces a new form of explicitly correlated factor in the context of the transcorrelated methods. The new correlation factor is obtained from the r12 ≈ 0 mathematical analysis of the transcorrelated Hamiltonian, and its analytical form is obtained such that the leading order in 1/r12 of the scalar part of the effective two-electron potential reproduces the long-range interaction of the range-separated density functional theory. The resulting correlation factor exactly imposes the cusp and is tuned by a unique parameter μ, which controls both the depth of the coulomb hole and its typical range in r12. The transcorrelated Hamiltonian obtained with such a new correlation factor has a straightforward analytical expression depending on the same parameter μ, and its physical contents continuously change by varying μ: One can change from a non-divergent repulsive Hamiltonian at large μ to a purely attractive one at small μ. We investigate the convergence of the ground state eigenvalues and right eigenvectors of such a new transcorrelated Hamiltonian as a function of the basis set and as a function of μ on a series of two-electron systems. We found that the convergence toward the complete basis set is much faster for quite a wide range of values of μ. We also propose a specific value of μ, which essentially reproduces the results obtained with the frozen Gaussian geminal introduced by Ten-no [Chem. Phys. Lett. 330, 169 (2000)].

Topics & Concepts

Hamiltonian (control theory)Eigenvalues and eigenvectorsMathematicsGaussianPhysicsStatistical physicsMathematical analysisMathematical physicsGeminalScalar (mathematics)Quantum mechanicsGround stateRadius of convergenceCoulombWave functionClassical mechanicsScalar potentialAdiabatic quantum computationSeries expansionHamiltonian mechanicsContext (archaeology)Basis (linear algebra)Scalar fieldAdvanced Chemical Physics StudiesAdvanced Physical and Chemical Molecular InteractionsQuantum Mechanics and Non-Hermitian Physics