Acoustic spontaneous emission by a superconducting qubit
ORAL
Abstract
Superconducting circuits are a versatile tool in developing hybrid quantum platforms, including interfacing with the bulk acoustic waves (BAWs) of pristine crystalline substrates [1]. Recent experimental work has shown that transmons have a reduced lifetime in the presence of piezoelectric thin films used to transduce microwave photons into phonons [2]. Here, we have designed a qubit architecture that extends the qubit's lifetime (T1) by an order of magnitude as compared to the previous quantum acoustic BAW device [2].
With these improvements and an increase in the electro-mechanical coupling, we observe weak dispersive interactions between the qubit and phonon. Furthermore, we measure the qubit's acoustic density of states to investigate the role of electro-mechanical coupling in limiting coherence.
[1] Y. Chu, et al. Science (2017)
[2] Y. Chu, et al. Nature (2018)
With these improvements and an increase in the electro-mechanical coupling, we observe weak dispersive interactions between the qubit and phonon. Furthermore, we measure the qubit's acoustic density of states to investigate the role of electro-mechanical coupling in limiting coherence.
[1] Y. Chu, et al. Science (2017)
[2] Y. Chu, et al. Nature (2018)
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Presenters
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Vijay Jain
Yale University
Authors
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Vijay Jain
Yale University
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Chan U Lei
Yale University, Applied Physics, Yale University
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Taekwan Yoon
Yale University
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Yanni Dahmani
Yale University
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Nikolay V. Gnezdilov
Yale University
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Vladislav Kurilovich
Yale University, Departments of Applied Physics and Physics, Yale University
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Luigi Frunzio
Applied Physics Department, Yale University, Yale University, Applied Physics, Yale University, Department of Applied Physics and Physics, Yale University
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Leonid Glazman
Yale University, Departments of Applied Physics and Physics, Yale University
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Peter Rakich
Yale University
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Robert J Schoelkopf
Yale University, Applied Physics, Yale University, Department of Applied Physics and Physics, Yale University