Litcius/Paper detail

Instanton theory of tunneling in molecules with asymmetric isotopic substitutions

Elena Jahr, Gabriel Laude, Jeremy O. Richardson

2020The Journal of Chemical Physics23 citationsDOIOpen Access PDF

Abstract

We consider quantum tunneling in asymmetric double-well systems for which the local minima in the two wells have the same energy, but the frequencies differ slightly. In a molecular context, this situation can arise if the symmetry is broken by isotopic substitutions. We derive a generalization of instanton theory for these asymmetric systems, leading to a semiclassical expression for the tunneling matrix element and hence the energy-level splitting. We benchmark the method using a set of one- and two-dimensional models, for which the results compare favorably with numerically exact quantum calculations. Using the ring-polymer instanton approach, we apply the method to compute the level splittings in various isotopomers of malonaldehyde in full dimensionality and analyze the relative contributions from the zero-point energy difference and tunneling effects.

Topics & Concepts

InstantonQuantum tunnellingSemiclassical physicsPhysicsMaxima and minimaQuantum mechanicsCurse of dimensionalityGeneralizationQuantumIsotopomersSymmetry (geometry)MoleculeBasis setFermionMatrix (chemical analysis)Set (abstract data type)Tunnel effectPotential energyBinding energyStatistical physicsChemistryDensity matrixAdvanced Chemical Physics StudiesAdvanced Physical and Chemical Molecular InteractionsSpectroscopy and Quantum Chemical Studies