Quantum electrodynamics near a photonic bandgap

Quantum electrodynamics near a photonic bandgap

Using a superconducting transmon qubit coupled to a microwave photonic crystal one can study intriguing strong-coupling effects such as the emergence of localized cavity modes within the photonic bandgap. Photonic crystals are a powerful tool for the manipulation of optical dispersion and density of...

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Bibliographic Details
Published in:Nature physics Vol. 13; no. 1; pp. 48 - 52
Main Authors: Liu, Yanbing, Houck, Andrew A.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-01-2017
Nature Publishing Group
Subjects:
639/624/400/482
639/766/1130/1064
639/766/483/3925
639/766/483/3926
Atomic
Classical and Continuum Physics
Complex Systems
Condensed Matter Physics
Crystals
Dissipation
Energy gaps (solid state)
Hybridization
letter
Mathematical and Computational Physics
Molecular
Nitrogen
Optical and Plasma Physics
Optics
Photonic band gaps
Photonic crystals
Photonics
Photons
Physics
Position (location)
Quantum electrodynamics
Quantum physics
Theoretical
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Description
Summary:Using a superconducting transmon qubit coupled to a microwave photonic crystal one can study intriguing strong-coupling effects such as the emergence of localized cavity modes within the photonic bandgap. Photonic crystals are a powerful tool for the manipulation of optical dispersion and density of states, and have thus been used in applications from photon generation to quantum sensing with nitrogen vacancy centres and atoms 1 , 2 . The unique control provided by these media makes them a beautiful, if unexplored, playground for strong-coupling quantum electrodynamics, where a single, highly nonlinear emitter hybridizes with the band structure of the crystal. Here we demonstrate that such a hybridization can create localized cavity modes that live within the photonic bandgap, whose localization and spectral properties we explore in detail. We then demonstrate that the coloured vacuum of the photonic crystal can be employed for efficient dissipative state preparation. This work opens exciting prospects for engineering long-range spin models 3 , 4 in the circuit quantum electrodynamics architecture, as well as new opportunities for dissipative quantum state engineering.
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ISSN:1745-2473
1745-2481
DOI:10.1038/nphys3834