Density-matrix description of partially coherent spin-orbit wave packets produced in short-laser-pulse photodetachment

Abstract

We investigate orbital alignment dynamics within the valence shell of atoms in coherently excited j=3/2,1/2 fine-structure manifolds generated by short-pulse photodetachment of F-, Cl- and Br- anions. Using Keldysh-type theory, we calculate the density matrix of the residual atoms generated by few-cycle pulses, whose elements determine the populations and coherence among the electronic states. Our calculations demonstrate that the degree of atomic coherence can be represented by a near universal function of the ratio between the pulse duration τp and the beat period τj'j of the atomic system, which allows one to characterize the coherence generated in atomic states.