P. R. Berman scite author profile

Quantum dots are typically formed from large groupings of atoms and thus may be expected to have appreciable many-body behavior under intense optical excitation. Nonetheless, they are known to exhibit discrete energy levels due to quantum confinement effects. We show that, like single-atom or single-molecule two- and three-level quantum systems, single semiconductor quantum dots can also exhibit interference phenomena when driven simultaneously by two optical fields. Probe absorption spectra are obtained that exhibit Autler-Townes splitting when the optical fields drive coupled transitions and complex Mollow-related structure, including gain without population inversion, when they drive the same transition. Our results open the way for the demonstration of numerous quantum level-based applications, such as quantum dot lasers, optical modulators, and quantum logic devices.

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Coherent population trapping of an electron spin in a single negatively charged quantum dot

Sun

et al. 2008

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P. R. Berman

Theory of Coherent Atomic Excitation

Coherent Optical Spectroscopy of a Strongly Driven Quantum Dot

Coherent population trapping of an electron spin in a single negatively charged quantum dot

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