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Molecules in Environments: Toward Systematic Quantum Embedding of Electrons and Drude Oscillators

Matej Ditte, Matteo Barborini, Leonardo Medrano Sandonas, Alexandre Tkatchenko

2023Physical Review Letters13 citationsDOIOpen Access PDF

Abstract

We develop a quantum embedding method that enables accurate and efficient treatment of interactions between molecules and an environment, while explicitly including many-body correlations. The molecule is composed of classical nuclei and quantum electrons, whereas the environment is modeled via charged quantum harmonic oscillators. We construct a general Hamiltonian and introduce a variational Ansatz for the correlated ground state of the fully interacting molecule-environment system. This wave function is optimized via the variational Monte Carlo method and the ground state energy is subsequently estimated through the diffusion Monte Carlo method. The proposed scheme allows an explicit many-body treatment of electrostatic, polarization, and dispersion interactions between the molecule and the environment. We study solvation energies and excitation energies of benzene derivatives, obtaining excellent agreement with explicit ab initio calculations and experiments.

Topics & Concepts

PhysicsQuantum Monte CarloAnsatzWave functionDiffusion Monte CarloAb initioVariational Monte CarloGround stateQuantumQuantum mechanicsElectronMonte Carlo methodHamiltonian (control theory)Statistical physicsHubbard modelMonte Carlo molecular modelingStatisticsMathematicsMarkov chain Monte CarloSuperconductivityMathematical optimizationAdvanced Chemical Physics StudiesMolecular Junctions and NanostructuresSpectroscopy and Quantum Chemical Studies
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