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Efficient local energy evaluation for multi-Slater wave functions in orbital space quantum Monte Carlo

Ankit Mahajan, Sandeep Sharma

2020The Journal of Chemical Physics19 citationsDOIOpen Access PDF

Abstract

We present an algorithm for calculating the local energy of a multi-Slater wave function in orbital space quantum Monte Carlo (QMC). Recent developments in selected configuration interaction methods have led to increased interest in using multi-Slater trial wave functions in various QMC methods. For an ab initio Hamiltonian, our algorithm has a cost scaling of O(n5 + nc), as opposed to the O(n4nc) scaling of existing orbital space algorithms, where n is the system size and nc is the number of configurations in the wave function. We present our method using variational Monte Carlo calculations with the Jastrow multi-Slater wave function, although the formalism should be applicable for auxiliary field QMC. We apply it to polyacetylene and demonstrate the possibility of using a much larger number of configurations than possible using existing methods.

Topics & Concepts

Quantum Monte CarloWave functionMonte Carlo methodPhysicsScalingStatistical physicsFormalism (music)Quantum mechanicsMonte Carlo molecular modelingMonte Carlo method in statistical physicsDynamic Monte Carlo methodHybrid Monte CarloVariational Monte CarloAb initioQuantumLinear scaleSlater determinantAuxiliary fieldSpace (punctuation)Full configuration interactionFunction (biology)Configuration spaceEnergy (signal processing)Field (mathematics)Monte Carlo integrationDiffusion Monte CarloQuasi-Monte Carlo methodQuantum, superfluid, helium dynamicsAdvanced Chemical Physics StudiesAdvanced Physical and Chemical Molecular Interactions
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