Mapping quantum state dynamics in spontaneous emission

The evolution of a quantum state undergoing radiative decay depends on how its emission is detected. If the emission is detected in the form of energy quanta, the evolution is characterized by a quantum jump to a lower energy state. In contrast, detection of the wave nature of the emitted radiation...

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Bibliographic Details
Published in:Nature communications 2016-05, Vol.7 (1), p.11527-11527, Article 11527
Main Authors: Naghiloo, M., Foroozani, N., Tan, D., Jadbabaie, A., Murch, K. W.
Format: Article
Language:English
Subjects:
639/624/400/482
639/766/483/1139
639/766/483/640
Humanities and Social Sciences
multidisciplinary
Radiation
Random variables
Science
Science (multidisciplinary)
Sensors
Tomography
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Summary:The evolution of a quantum state undergoing radiative decay depends on how its emission is detected. If the emission is detected in the form of energy quanta, the evolution is characterized by a quantum jump to a lower energy state. In contrast, detection of the wave nature of the emitted radiation leads to different dynamics. Here, we investigate the diffusive dynamics of a superconducting artificial atom under continuous homodyne detection of its spontaneous emission. Using quantum state tomography, we characterize the correlation between the detected homodyne signal and the emitter’s state, and map out the conditional back-action of homodyne measurement. By tracking the diffusive quantum trajectories of the state as it decays, we characterize selective stochastic excitation induced by the choice of measurement basis. Our results demonstrate dramatic differences from the quantum jump evolution associated with photodetection and highlight how continuous field detection can be harnessed to control quantum evolution. The evolution of a quantum state undergoing radiative decay depends on how the emission is detected. Here, the authors demonstrate how continuous field detection, as opposed to the more common detection of energy quanta, allows control of the back-action on the emitter’s state.
ISSN:2041-1723
2041-1723
DOI:10.1038/ncomms11527