Author
Listed:
- Bharath Kannan
(Massachusetts Institute of Technology
Massachusetts Institute of Technology)
- Max J. Ruckriegel
(Massachusetts Institute of Technology)
- Daniel L. Campbell
(Massachusetts Institute of Technology)
- Anton Frisk Kockum
(Chalmers University of Technology)
- Jochen Braumüller
(Massachusetts Institute of Technology)
- David K. Kim
(MIT Lincoln Laboratory)
- Morten Kjaergaard
(Massachusetts Institute of Technology)
- Philip Krantz
(Massachusetts Institute of Technology
Chalmers University of Technology)
- Alexander Melville
(MIT Lincoln Laboratory)
- Bethany M. Niedzielski
(MIT Lincoln Laboratory)
- Antti Vepsäläinen
(Massachusetts Institute of Technology)
- Roni Winik
(Massachusetts Institute of Technology)
- Jonilyn L. Yoder
(MIT Lincoln Laboratory)
- Franco Nori
(RIKEN Cluster for Pioneering Research
The University of Michigan)
- Terry P. Orlando
(Massachusetts Institute of Technology
Massachusetts Institute of Technology)
- Simon Gustavsson
(Massachusetts Institute of Technology)
- William D. Oliver
(Massachusetts Institute of Technology
Massachusetts Institute of Technology
MIT Lincoln Laboratory
Massachusetts Institute of Technology)
Abstract
Models of light–matter interactions in quantum electrodynamics typically invoke the dipole approximation1,2, in which atoms are treated as point-like objects when compared to the wavelength of the electromagnetic modes with which they interact. However, when the ratio between the size of the atom and the mode wavelength is increased, the dipole approximation no longer holds and the atom is referred to as a ‘giant atom’2,3. So far, experimental studies with solid-state devices in the giant-atom regime have been limited to superconducting qubits that couple to short-wavelength surface acoustic waves4–10, probing the properties of the atom at only a single frequency. Here we use an alternative architecture that realizes a giant atom by coupling small atoms to a waveguide at multiple, but well separated, discrete locations. This system enables tunable atom–waveguide couplings with large on–off ratios3 and a coupling spectrum that can be engineered by the design of the device. We also demonstrate decoherence-free interactions between multiple giant atoms that are mediated by the quasi-continuous spectrum of modes in the waveguide—an effect that is not achievable using small atoms11. These features allow qubits in this architecture to switch between protected and emissive configurations in situ while retaining qubit–qubit interactions, opening up possibilities for high-fidelity quantum simulations and non-classical itinerant photon generation12,13.
Suggested Citation
Bharath Kannan & Max J. Ruckriegel & Daniel L. Campbell & Anton Frisk Kockum & Jochen Braumüller & David K. Kim & Morten Kjaergaard & Philip Krantz & Alexander Melville & Bethany M. Niedzielski & Antt, 2020.
"Waveguide quantum electrodynamics with superconducting artificial giant atoms,"
Nature, Nature, vol. 583(7818), pages 775-779, July.
Handle:
RePEc:nat:nature:v:583:y:2020:i:7818:d:10.1038_s41586-020-2529-9
DOI: 10.1038/s41586-020-2529-9
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Citations
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Cited by:
- Zi-Qi Wang & Yi-Pu Wang & Jiguang Yao & Rui-Chang Shen & Wei-Jiang Wu & Jie Qian & Jie Li & Shi-Yao Zhu & J. Q. You, 2022.
"Giant spin ensembles in waveguide magnonics,"
Nature Communications, Nature, vol. 13(1), pages 1-7, December.
- A. Hashemi & K. Busch & D. N. Christodoulides & S. K. Ozdemir & R. El-Ganainy, 2022.
"Linear response theory of open systems with exceptional points,"
Nature Communications, Nature, vol. 13(1), pages 1-12, December.
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