Litcius/Paper detail

Quantum dynamics using path integral coarse-graining

Félix Musil, Iryna Zaporozhets, Frank Noé, Cecilia Clementi, Venkat Kapil

2022The Journal of Chemical Physics44 citationsDOIOpen Access PDF

Abstract

The vibrational spectra of condensed and gas-phase systems are influenced by thequantum-mechanical behavior of light nuclei. Full-dimensional simulations of approximate quantum dynamics are possible thanks to the imaginary time path-integral (PI) formulation of quantum statistical mechanics, albeit at a high computational cost which increases sharply with decreasing temperature. By leveraging advances in machine-learned coarse-graining, we develop a PI method with the reduced computational cost of a classical simulation. We also propose a simple temperature elevation scheme to significantly attenuate the artifacts of standard PI approaches as well as eliminate the unfavorable temperature scaling of the computational cost. We illustrate the approach, by calculating vibrational spectra using standard models of water molecules and bulk water, demonstrating significant computational savings and dramatically improved accuracy compared to more expensive reference approaches. Our simple, efficient, and accurate method has prospects for routine calculations of vibrational spectra for a wide range of molecular systems - with an explicit treatment of the quantum nature of nuclei.

Topics & Concepts

GranularityPath integral formulationMolecular dynamicsQuantumStatistical physicsPath (computing)ScalingImaginary timeRange (aeronautics)Spectral lineComputational complexity theorySimple (philosophy)PhysicsComputer scienceQuantum dynamicsComputational physicsQuantum mechanicsAlgorithmMathematicsMaterials scienceComposite materialEpistemologyProgramming languagePhilosophySupersymmetric quantum mechanicsOperating systemGeometryQuantum, superfluid, helium dynamicsSpectroscopy and Quantum Chemical StudiesAdvanced NMR Techniques and Applications