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Nondestructive dispersive imaging of rotationally excited ultracold molecules

A barrier to realizing the potential of molecules for quantum information science applications is a lack of high-fidelity, single-molecule imaging techniques. Here, we present and theoretically analyze a general scheme for dispersive imaging of electronic ground-state molecules. Our technique relies on the intrinsic anisotropy of excited molecular rotational states to generate optical birefringence, which can be detected through polarization rotation of an off-resonant probe laser beam. Using \narb and \rbcs as examples, we construct a formalism for choosing the molecular state to be imaged and the excited electronic states involved in off-resonant coupling. Our proposal establishes the relevant parameters for achieving degree-level polarization rotations for bulk molecular gases, thus enabling high-fidelity nondestructive imaging. We additionally outline requirements for the high-fidelity imaging of individually trapped molecules.

preprint2020arXivOpen access
Qingze GuanMichael HighmanEric J. MeierGarrett R. WilliamsVito ScarolaSvetlana KotochigovaBrian DeMarcoBryce Gadway
physics.atom-phquant-ph
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Qingze GuanMichael HighmanEric J. MeierGarrett R. WilliamsVito ScarolaSvetlana KotochigovaBrian DeMarcoBryce Gadway

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