Efficient quantum dynamics simulations of complex molecular systems: A unified treatment of dynamic and static disorder
Maxim F. Gelin, Amalia Velardo, Raffaele Borrelli
Abstract
We present a unified and highly numerically efficient formalism for the simulation of quantum dynamics of complex molecular systems, which takes into account both temperature effects and static disorder. The methodology is based on the thermo-field dynamics formalism, and Gaussian static disorder is included into simulations via auxiliary bosonic operators. This approach, combined with the tensor-train/matrix-product state representation of the thermalized stochastic wave function, is applied to study the effect of dynamic and static disorders in charge-transfer processes in model organic semiconductor chains employing the Su-Schrieffer-Heeger (Holstein-Peierls) model Hamiltonian.
Topics & Concepts
Hamiltonian (control theory)Statistical physicsMolecular dynamicsGaussianQuantumFormalism (music)PhysicsWave functionQuantum mechanicsMathematicsArtMathematical optimizationMusicalVisual artsSpectroscopy and Quantum Chemical StudiesQuantum many-body systemsAdvanced Chemical Physics Studies