Tailoring quantum superpositions with linearly polarized   amplitude-modulated light

S. Pustelny; M. Koczwara; L. Cincio; and W. Gawlik

arXiv:1012.4453·physics.atom-ph·May 20, 2015

Tailoring quantum superpositions with linearly polarized amplitude-modulated light

S. Pustelny, M. Koczwara, L. Cincio, and W. Gawlik

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TL;DR

This paper demonstrates how to generate and detect specific quantum superpositions in rubidium atoms using amplitude-modulated light, with controllable efficiency through tuning experimental parameters.

Contribution

It introduces a method for controllably creating and detecting ground-state superpositions in rubidium using amplitude-modulated nonlinear magneto-optical rotation.

Findings

01

Efficient creation of specific quantum superpositions achieved.

02

Control over coherence generation via modulation frequency and magnetic field.

03

Analysis of process dependence on experimental parameters.

Abstract

Amplitude-modulated nonlinear magneto-optical rotation is a powerful technique that offers a possibility of controllable generation of given quantum states. In this paper, we demonstrate creation and detection of specific ground-state magnetic-sublevel superpositions in $^{87}$ Rb. By appropriate tuning of the modulation frequency and magnetic-field induction the efficiency of a given coherence generation is controlled. The processes are analyzed versus different experimental parameters.S

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