Stabilization of Qubit Relaxation Rates by Frequency Modulation

Shlomi Matityahu; Alexander Shnirman; Moshe Schechter

doi:10.1103/PhysRevApplied.16.044036

Stabilization of Qubit Relaxation Rates by Frequency Modulation

Shlomi Matityahu, Alexander Shnirman, Moshe Schechter

Department of Physics

Ben-Gurion University of the Negev

Research output: Contribution to journal › Article › peer-review

Abstract

Temporal, spectral, and sample-to-sample fluctuations in coherence properties of qubits form an outstanding challenge for the development of upscaled fault-tolerant quantum computers. A ubiquitous source for these fluctuations in superconducting qubits is a set of atomic scale defects with a two-level structure. Here we propose a way to mitigate these fluctuations and stabilize the qubit performance. We show that frequency modulation of a qubit or, alternatively, of the two-level defects, leads to averaging of the qubit relaxation rate over a wide interval of frequencies.

Original language	American English
Article number	A69
Journal	Physical Review Applied
Volume	16
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevApplied.16.044036
State	Published - 20 Oct 2021

Keywords

cond-mat.mes-hall
quant-ph

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevApplied.16.044036

Cite this

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abstract = "Temporal, spectral, and sample-to-sample fluctuations in coherence properties of qubits form an outstanding challenge for the development of upscaled fault-tolerant quantum computers. A ubiquitous source for these fluctuations in superconducting qubits is a set of atomic scale defects with a two-level structure. Here we propose a way to mitigate these fluctuations and stabilize the qubit performance. We show that frequency modulation of a qubit or, alternatively, of the two-level defects, leads to averaging of the qubit relaxation rate over a wide interval of frequencies.",

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N2 - Temporal, spectral, and sample-to-sample fluctuations in coherence properties of qubits form an outstanding challenge for the development of upscaled fault-tolerant quantum computers. A ubiquitous source for these fluctuations in superconducting qubits is a set of atomic scale defects with a two-level structure. Here we propose a way to mitigate these fluctuations and stabilize the qubit performance. We show that frequency modulation of a qubit or, alternatively, of the two-level defects, leads to averaging of the qubit relaxation rate over a wide interval of frequencies.

AB - Temporal, spectral, and sample-to-sample fluctuations in coherence properties of qubits form an outstanding challenge for the development of upscaled fault-tolerant quantum computers. A ubiquitous source for these fluctuations in superconducting qubits is a set of atomic scale defects with a two-level structure. Here we propose a way to mitigate these fluctuations and stabilize the qubit performance. We show that frequency modulation of a qubit or, alternatively, of the two-level defects, leads to averaging of the qubit relaxation rate over a wide interval of frequencies.

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JF - Physical Review Applied

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ER -

Stabilization of Qubit Relaxation Rates by Frequency Modulation

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Keywords

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