Moving beyond the Transmon: Noise-Protected Superconducting Quantum Circuits

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Standard

Moving beyond the Transmon : Noise-Protected Superconducting Quantum Circuits. / Gyenis, Andras; Di Paolo, Agustin; Koch, Jens; Blais, Alexandre; Houck, Andrew A.; Schuster, David.

I: Prx quantum, Bind 2, Nr. 3, 030101, 02.09.2021.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Gyenis, A, Di Paolo, A, Koch, J, Blais, A, Houck, AA & Schuster, D 2021, 'Moving beyond the Transmon: Noise-Protected Superconducting Quantum Circuits', Prx quantum, bind 2, nr. 3, 030101. https://doi.org/10.1103/PRXQuantum.2.030101

APA

Gyenis, A., Di Paolo, A., Koch, J., Blais, A., Houck, A. A., & Schuster, D. (2021). Moving beyond the Transmon: Noise-Protected Superconducting Quantum Circuits. Prx quantum, 2(3), [030101]. https://doi.org/10.1103/PRXQuantum.2.030101

Vancouver

Gyenis A, Di Paolo A, Koch J, Blais A, Houck AA, Schuster D. Moving beyond the Transmon: Noise-Protected Superconducting Quantum Circuits. Prx quantum. 2021 sep. 2;2(3). 030101. https://doi.org/10.1103/PRXQuantum.2.030101

Author

Gyenis, Andras ; Di Paolo, Agustin ; Koch, Jens ; Blais, Alexandre ; Houck, Andrew A. ; Schuster, David. / Moving beyond the Transmon : Noise-Protected Superconducting Quantum Circuits. I: Prx quantum. 2021 ; Bind 2, Nr. 3.

Bibtex

@article{bfd7bdad4ce848fbbde4f8532554bda9,
title = "Moving beyond the Transmon: Noise-Protected Superconducting Quantum Circuits",
abstract = "Artificial atoms realized by superconducting circuits offer unique opportunities to store and process quantum information with high fidelity. Among them, implementations of circuits that harness intrinsic noise protection have been rapidly developed in recent years. These noise-protected devices constitute a new class of qubits in which the computational states are largely decoupled from local noise channels. The main challenges in engineering such systems are simultaneously guarding against both bit- and phase-flip errors, and also ensuring high-fidelity qubit control. Although partial noise protection is possible in superconducting circuits relying on a single quantum degree of freedom, the promise of complete protection can only be fulfilled by implementing multimode or hybrid circuits. This Perspective reviews the theoretical principles at the heart of these new qubits, describes recent experiments, and highlights the potential of robust encoding of quantum information in superconducting qubits.",
keywords = "ERROR-CORRECTION, STATE, QUBITS, COHERENCE, SUPREMACY",
author = "Andras Gyenis and {Di Paolo}, Agustin and Jens Koch and Alexandre Blais and Houck, {Andrew A.} and David Schuster",
year = "2021",
month = sep,
day = "2",
doi = "10.1103/PRXQuantum.2.030101",
language = "English",
volume = "2",
journal = "Prx quantum",
issn = "2691-3399",
publisher = "AMER PHYSICAL SOC",
number = "3",

}

RIS

TY - JOUR

T1 - Moving beyond the Transmon

T2 - Noise-Protected Superconducting Quantum Circuits

AU - Gyenis, Andras

AU - Di Paolo, Agustin

AU - Koch, Jens

AU - Blais, Alexandre

AU - Houck, Andrew A.

AU - Schuster, David

PY - 2021/9/2

Y1 - 2021/9/2

N2 - Artificial atoms realized by superconducting circuits offer unique opportunities to store and process quantum information with high fidelity. Among them, implementations of circuits that harness intrinsic noise protection have been rapidly developed in recent years. These noise-protected devices constitute a new class of qubits in which the computational states are largely decoupled from local noise channels. The main challenges in engineering such systems are simultaneously guarding against both bit- and phase-flip errors, and also ensuring high-fidelity qubit control. Although partial noise protection is possible in superconducting circuits relying on a single quantum degree of freedom, the promise of complete protection can only be fulfilled by implementing multimode or hybrid circuits. This Perspective reviews the theoretical principles at the heart of these new qubits, describes recent experiments, and highlights the potential of robust encoding of quantum information in superconducting qubits.

AB - Artificial atoms realized by superconducting circuits offer unique opportunities to store and process quantum information with high fidelity. Among them, implementations of circuits that harness intrinsic noise protection have been rapidly developed in recent years. These noise-protected devices constitute a new class of qubits in which the computational states are largely decoupled from local noise channels. The main challenges in engineering such systems are simultaneously guarding against both bit- and phase-flip errors, and also ensuring high-fidelity qubit control. Although partial noise protection is possible in superconducting circuits relying on a single quantum degree of freedom, the promise of complete protection can only be fulfilled by implementing multimode or hybrid circuits. This Perspective reviews the theoretical principles at the heart of these new qubits, describes recent experiments, and highlights the potential of robust encoding of quantum information in superconducting qubits.

KW - ERROR-CORRECTION

KW - STATE

KW - QUBITS

KW - COHERENCE

KW - SUPREMACY

U2 - 10.1103/PRXQuantum.2.030101

DO - 10.1103/PRXQuantum.2.030101

M3 - Journal article

VL - 2

JO - Prx quantum

JF - Prx quantum

SN - 2691-3399

IS - 3

M1 - 030101

ER -

ID: 279625048