Litcius/Paper detail

Dissipative Equation of Motion for Electromagnetic Radiation in Quantum Dynamics

Carlos M. Bustamante, Esteban D. Gadea, Andrew P. Horsfield, Tchavdar N. Todorov, Mariano C. González Lebrero, Damián A. Scherlis

2021Physical Review Letters19 citationsDOIOpen Access PDF

Abstract

The dynamical description of the radiative decay of an electronically excited state in realistic many-particle systems is an unresolved challenge. In the present investigation electromagnetic radiation of the charge density is approximated as the power dissipated by a classical dipole, to cast the emission in closed form as a unitary single-electron theory. This results in a formalism of unprecedented efficiency, critical for ab initio modeling, which exhibits at the same time remarkable properties: it quantitatively predicts decay rates, natural broadening, and absorption intensities. Exquisitely accurate excitation lifetimes are obtained from time-dependent DFT simulations for C^{2+}, B^{+}, and Be, of 0.565, 0.831, and 1.97 ns, respectively, in accord with experimental values of 0.57±0.02, 0.86±0.07, and 1.77-2.5 ns. Hence, the present development expands the frontiers of quantum dynamics, bringing within reach first-principles simulations of a wealth of photophysical phenomena, from fluorescence to time-resolved spectroscopies.

Topics & Concepts

PhysicsExcited stateDissipative systemQuantumExcitationAtomic physicsElectronRadiative transferElectromagnetic radiationQuantum dynamicsDipoleQuantum mechanicsQuantum electrodynamicsAdvanced Chemical Physics StudiesSpectroscopy and Quantum Chemical StudiesQuantum and electron transport phenomena