Abstract

We systematically investigate the electromagnetically induced transparency (EIT) and slow light properties in ultracold Bose and Fermi gases. It shows a very different property from the classical theory, which assumes frozen atomic motion. For example, the speed of light inside the atomic gases can be changed significantly near the Bose–Einstein condensation temperature, while the presence of the Fermi sea can destroy the EIT effect even at zero temperature. From an experimental point of view, such quantum EIT property is mostly manifested in the counterpropagating excitation schemes in either the low-lying Rydberg transition with a narrow linewidth or in the D2 transitions with a weak coupling field. We further investigate the interaction effects on the EIT for a weakly interacting Bose–Einstein condensate, showing an inhomogeneous broadening of the EIT profile and nontrivial change of the light speed due to the quantum depletion other than mean-field energy shifts.

© 2013 Optical Society of America

Extracting dynamical Green’s function of ultracold quantum gases via electromagnetically induced transparency

H. H. Jen and Daw-Wei Wang
J. Opt. Soc. Am. B 31(12) 2931-2937 (2014)

Quantum random walks in a coherent atomic system via electromagnetically induced transparency

Yun Li, Chao Hang, Lei Ma, Weiping Zhang, and Guoxiang Huang
J. Opt. Soc. Am. B 25(12) C39-C45 (2008)

Electromagnetically induced transparency in a spin-orbit coupled Bose-Einstein condensate

Zhengfeng Hu, Chengpu Liu, Jin-Ming Liu, and Yuzhu Wang
Opt. Express 26(16) 20122-20131 (2018)

Marking slow light signals with fast optical precursors in the regime of electromagnetically induced transparency

Qian-Qian Bao, Bo Fang, Xin Yang, Cui-Li Cui, and Jin-Hui Wu
J. Opt. Soc. Am. B 31(1) 62-66 (2014)

Atom and field squeezed output of three-level atom laser surrounded by a Kerr medium in the electromagnetically induced transparency regime

Ebrahim Ghasemian and Mohammad Kazem Tavassoly
J. Opt. Soc. Am. B 35(1) 86-94 (2018)