Double-quantum spectroscopy of dense atomic vapors: interplay between Doppler and self-broadenings

Abstract

In this article, we present a simulation study of the linear and nonlinear spectroscopy of dense atomic vapors. Motivated by recent experiments, we focus on double quantum spectroscopy which directly probes dipole-dipole interactions. By including explicitly thermal velocity, we show that temperature has an important impact on the self-broadening mechanism of the linear and nonlinear spectra. We also provide analytical expressions for the response functions in the short time limit using the two-body approximation which shows that double quantum spectroscopy for atomic vapors directly probes the transition amplitude of the electronic excitation between two atoms. We also propose an expression for the double quantum spectrum that includes the effect of Doppler broadening and we discuss the effect of density on the spectrum. We show that when Doppler broadening is negligible compared to self-broadening the double quantum spectrum scales with the atomic density while when Doppler broadening dominates it scales as the square of the density.