Litcius/Paper detail

Quantum Trajectories for the Dynamics in the Exact Factorization Framework: A Proof-of-Principle Test

Francesco Talotta, Federica Agostini, Giovanni Ciccotti

2020The Journal of Physical Chemistry A25 citationsDOI

Abstract

In the framework of the exact factorization of the time-dependent electron-nuclear wave function, we investigate the possibility of solving the nuclear time-dependent Schrödinger equation based on trajectories. The nuclear equation is separated in a Hamilton-Jacobi equation for the phase of the wave function, and a continuity equation for its (squared) modulus. For illustrative adiabatic and nonadiabatic one-dimensional models, we implement a procedure to follow the evolution of the nuclear density along the characteristics of the Hamilton-Jacobi equation. Those characteristics are referred to as quantum trajectories, since they are generated via ordinary differential equations similar to Hamilton's equations, but including the so-called quantum potential, and they can be used to reconstruct exactly the quantum-mechanical nuclear wave function, provided infinite initial conditions are propagated in time.

Topics & Concepts

Wave functionSchrödinger equationFactorizationAdiabatic processQuantumMathematicsExact differential equationPhysicsDifferential equationClassical mechanicsQuantum mechanicsOrdinary differential equationMathematical analysisAlgorithmSpectroscopy and Quantum Chemical StudiesAdvanced Chemical Physics StudiesQuantum Information and Cryptography