Litcius/Paper detail

Nonadiabatic vibronic effects in single-molecule junctions: A theoretical study using the hierarchical equations of motion approach

Christoph Kaspar, André Erpenbeck, Jakob Bätge, C. Schinabeck, Michael Thoss

2022Physical review. B./Physical review. B13 citationsDOI

Abstract

The interaction between electronic and vibrational degrees of freedom is an important mechanism in nonequilibrium charge transport through molecular nanojunctions. While adiabatic polaron-type coupling has been studied in great detail, new transport phenomena arise for nonadiabatic coupling scenarios corresponding to a breakdown of the Born-Oppenheimer approximation. Employing the numerically exact hierarchical equations of motion approach, we analyze the effect of nonadiabatic electronic-vibrational coupling on electron transport in molecular junctions considering a series of models with increasing complexity. The results reveal a significant influence of nonadiabatic coupling on the transport characteristics and a variety of interesting effects, including negative differential conductance. The underlying mechanisms are analyzed in detail.

Topics & Concepts

Adiabatic processVibronic couplingPolaronCoupling (piping)PhysicsDegrees of freedom (physics and chemistry)Adiabatic theoremNon-equilibrium thermodynamicsEquations of motionBorn–Oppenheimer approximationMolecular vibrationQuantum mechanicsMoleculeClassical mechanicsElectronMaterials scienceMetallurgyMolecular Junctions and NanostructuresQuantum and electron transport phenomenaNanowire Synthesis and Applications