Controlled dc Monitoring of a Superconducting Qubit

A. Kringhoj; T. W. Larsen; B. van Heck; D. Sabonis; O. Erlandsson; Ivana Petkovic; D. Pikulin; P. Krogstrup; K. D. Petersson; C. M. Marcus

doi:10.1103/PhysRevLett.124.056801

Controlled dc Monitoring of a Superconducting Qubit

A. Kringhoj^*, T. W. Larsen, B. van Heck, D. Sabonis, O. Erlandsson, Ivana Petkovic, D. Pikulin, P. Krogstrup, K. D. Petersson, C. M. Marcus

^*Corresponding author for this work

Condensed Matter Physics

Research output: Contribution to journal › Journal article › Research › peer-review

13 Citations (Scopus)

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Abstract

Creating a transmon qubit using semiconductor-superconductor hybrid materials not only provides electrostatic control of the qubit frequency, it also allows parts of the circuit to be electrically connected and disconnected in situ by operating a semiconductor region of the device as a field-effect transistor. Here, we exploit this feature to compare in the same device characteristics of the qubit, such as frequency and relaxation time, with related transport properties such as critical supercurrent and normal-state resistance. Gradually opening the field-effect transistor to the monitoring circuit allows the influence of weak-to-strong dc monitoring of a "live" qubit to be measured. A model of this influence yields excellent agreement with experiment, demonstrating a relaxation rate mediated by a gate-controlled environmental coupling.

Original language	English
Article number	056801
Journal	Physical Review Letters
Volume	124
Issue number	5
Number of pages	6
ISSN	0031-9007
DOIs	https://doi.org/10.1103/PhysRevLett.124.056801
Publication status	Published - 5 Feb 2020

Keywords

GAP

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Cite this

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title = "Controlled dc Monitoring of a Superconducting Qubit",

abstract = "Creating a transmon qubit using semiconductor-superconductor hybrid materials not only provides electrostatic control of the qubit frequency, it also allows parts of the circuit to be electrically connected and disconnected in situ by operating a semiconductor region of the device as a field-effect transistor. Here, we exploit this feature to compare in the same device characteristics of the qubit, such as frequency and relaxation time, with related transport properties such as critical supercurrent and normal-state resistance. Gradually opening the field-effect transistor to the monitoring circuit allows the influence of weak-to-strong dc monitoring of a {"}live{"} qubit to be measured. A model of this influence yields excellent agreement with experiment, demonstrating a relaxation rate mediated by a gate-controlled environmental coupling.",

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T1 - Controlled dc Monitoring of a Superconducting Qubit

AU - Kringhoj, A.

AU - Larsen, T. W.

AU - van Heck, B.

AU - Sabonis, D.

AU - Erlandsson, O.

AU - Petkovic, Ivana

AU - Pikulin, D.

AU - Krogstrup, P.

AU - Petersson, K. D.

AU - Marcus, C. M.

PY - 2020/2/5

Y1 - 2020/2/5

N2 - Creating a transmon qubit using semiconductor-superconductor hybrid materials not only provides electrostatic control of the qubit frequency, it also allows parts of the circuit to be electrically connected and disconnected in situ by operating a semiconductor region of the device as a field-effect transistor. Here, we exploit this feature to compare in the same device characteristics of the qubit, such as frequency and relaxation time, with related transport properties such as critical supercurrent and normal-state resistance. Gradually opening the field-effect transistor to the monitoring circuit allows the influence of weak-to-strong dc monitoring of a "live" qubit to be measured. A model of this influence yields excellent agreement with experiment, demonstrating a relaxation rate mediated by a gate-controlled environmental coupling.

AB - Creating a transmon qubit using semiconductor-superconductor hybrid materials not only provides electrostatic control of the qubit frequency, it also allows parts of the circuit to be electrically connected and disconnected in situ by operating a semiconductor region of the device as a field-effect transistor. Here, we exploit this feature to compare in the same device characteristics of the qubit, such as frequency and relaxation time, with related transport properties such as critical supercurrent and normal-state resistance. Gradually opening the field-effect transistor to the monitoring circuit allows the influence of weak-to-strong dc monitoring of a "live" qubit to be measured. A model of this influence yields excellent agreement with experiment, demonstrating a relaxation rate mediated by a gate-controlled environmental coupling.

KW - GAP

U2 - 10.1103/PhysRevLett.124.056801

DO - 10.1103/PhysRevLett.124.056801

M3 - Journal article

SN - 0031-9007

VL - 124

JO - Physical Review Letters

JF - Physical Review Letters

IS - 5

M1 - 056801

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