Litcius/Paper detail

Fast Screening of Minimum Energy Crossing Points with Semiempirical Tight-Binding Methods

Philipp Pracht, Christoph Bannwarth

2022Journal of Chemical Theory and Computation22 citationsDOI

Abstract

The investigation of photochemical processes is a highly active field in computational chemistry. One research direction is the automated exploration and identification of minimum energy conical intersection (MECI) geometries. However, due to the immense technical effort required to calculate nonadiabatic potential energy landscapes, the routine application of such computational protocols is severely limited. In this study, we will discuss the prospect of combining adiabatic potential energy surfaces from semiempirical quantum mechanical calculations with specialized confinement potential and metadynamics simulations to identify S0/T1 minimum energy crossing point (MECP) geometries. It is shown that MECPs calculated at the GFN2-xTB level can provide suitable approximations to high-level S0/S1ab initio conical intersection geometries at a fraction of the computational cost. Reference MECIs of benzene are studied to illustrate the basic concept. An example application of the presented protocol is demonstrated for a set of photoswitch molecules.

Topics & Concepts

Conical intersectionMetadynamicsPotential energyIntersection (aeronautics)Ab initioComputer scienceAdiabatic processQuantum chemistryAb initio quantum chemistry methodsComputational chemistryStatistical physicsPhysicsMoleculeChemistryMolecular dynamicsQuantum mechanicsAerospace engineeringEngineeringSupramolecular chemistryPhotochromic and Fluorescence ChemistrySpectroscopy and Quantum Chemical StudiesPhotochemistry and Electron Transfer Studies