Power-Broadening-Free Correlation Spectroscopy in Cold Atoms
arXiv:1308.0849 · doi:10.1103/PhysRevA.88.033812
Abstract
We report a detailed investigation on the properties of correlation spectra for cold atoms under the condition of Electromagnetically Induced Transparency (EIT). We describe the transition in the system from correlation to anti-correlation as the intensity of the fields increases. Such transition occurs for laser frequencies around the EIT resonance, which is characterized by a correlation peak. The transition point between correlation and anti-correlation is independent of power broadening and provides directly the ground-state coherence time. We introduce a method to extract in real time the correlation spectra of the system. The experiments were done in two distinct magneto-optical traps (MOT), one for cesium and the other for rubidium atoms, employing different detection schemes. A simplified theory is introduced assuming three-level atoms in $Î$ configuration interacting with a laser with stochastic phase fluctuations, providing a good agreement with the experimental observations.
8 pages, 10 figures, submitted to Physical Review A