Computer modeling of fluorescence dip spectroscopy with pulsed laser excitation

Abstract

This article is an electronic publication in Spectrochimica Acta Electronica (SAE), the electronic section of Spectrochimica Acta Part B (SAB). The hard copy text is accompanied by a disk with a demonstration program, block libraries, demonstration files, and ancillary files. The article discusses the computer modeling of fluorescence dip spectroscopy, a relatively new and powerful atomic diagnostic technique. The models were found to agree essentially perfectly with previously published photostationary results and to extend those results to the more realistic laser temporal profiles encountered in actual experiments. The fluorescence dip parameters were found to be robust so long as the system under study approached saturation conditions. Short, noisy laser pulses were found to be acceptable, for determination of the fluorescence dip parameters, provided the laser pulses were sufficiently intense to cause near saturation of the three level system. Conversely, steady state excitation was not found to be crucial to the determination of accurate fluorescence dip parameters. For a five level model of the silver atomic system, “negative fluorescence dips” were readily found in the simulations, even though some of the relevant parameters were rough estimates of the actual, unknown parameters.