Quantum effects in the interaction of off-resonant coherent light with a single atom

TL;DR

This paper explores how off-resonant coherent light interacts with a single atom, demonstrating quantum-controlled shifts and superpositions of light states, with implications for quantum information processing.

Contribution

It investigates conditions for suppressing multi-photon scattering and achieving large coherent shifts, advancing the understanding of quantum light-atom interactions.

Findings

Quantum controlled coherent shifts are achievable with sufficiently long pulses.

Multi-photon scattering effects, especially four-wave mixing, are characterized.

Potential for generating superpositions of large-amplitude coherent states.

Abstract

Well controlled nonlinear interactions between light field pulses and single atoms could be used to implement optical quantum information technologies based on qubits encoded in superpositions of coherent states of light. Here, we investigate the transformation of a coherent light field input at a single atom sufficiently far from resonance to limit the decoherence effects associated with random excitations of the atom. The conditions for suppressing multi-photon scattering to implement arbitrarily large shifts of the coherent light amplitude without decoherence are studied. It is shown that quantum controlled coherent shifts can be achieved by sufficiently long coherent pulses, indicating the possibility of generating superpositions of coherent states with large amplitude differences. The dominant multi-photon scattering effect associated with four wave mixing is also identified, and the spectral and temporal characteristics of the entangled photon pairs generated by this process are discussed.