Fast microwave-driven three-qubit gates for cavity-coupled superconducting qubits

Edwin Barnes; Christian Arenz; Alexander James Gordon Pitchford; Sophia E. Economou

doi:10.1103/PhysRevB.96.024504

Fast microwave-driven three-qubit gates for cavity-coupled superconducting qubits

Edwin Barnes, Christian Arenz, Alexander James Gordon Pitchford, Sophia E. Economou

Adran Ffiseg

Allbwn ymchwil: Cyfraniad at gyfnodolyn › Erthygl › adolygiad gan gymheiriaid

21 Dyfyniadau (Scopus)

137 Wedi eu Llwytho i Lawr (Pure)

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Although single- and two-qubit gates are sufficient for universal quantum computation, single-shot three-qubit gates greatly simplify quantum error correction schemes and algorithms. We design fast, high-fidelity three-qubit entangling gates based on microwave pulses for transmon qubits coupled through a superconducting resonator. We show that when interqubit frequency differences are comparable to single-qubit anharmonicities, errors occur primarily through a single unwanted transition. This feature enables the design of fast three-qubit gates based on simple analytical pulse shapes that are engineered to minimize such errors. We show that a three-qubit ccz gate can be performed in 260 ns with fidelities exceeding
99.38%, or 99.99% with numerical optimization.

Iaith wreiddiol	Saesneg
Rhif yr erthygl	024504
Cyfnodolyn	Physical Review B
Cyfrol	96
Rhif cyhoeddi	2
Dynodwyr Gwrthrych Digidol (DOIs)	https://doi.org/10.1103/PhysRevB.96.024504
Statws	Cyhoeddwyd - 06 Gorff 2017

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10.1103/PhysRevB.96.024504

Fast microwave-driven three-qubit gates for cavity-coupled superconducting quibitsLlawysgrif awdur wedi’i dderbyn, 506 KB

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title = "Fast microwave-driven three-qubit gates for cavity-coupled superconducting qubits",

abstract = "Although single- and two-qubit gates are sufficient for universal quantum computation, single-shot three-qubit gates greatly simplify quantum error correction schemes and algorithms. We design fast, high-fidelity three-qubit entangling gates based on microwave pulses for transmon qubits coupled through a superconducting resonator. We show that when interqubit frequency differences are comparable to single-qubit anharmonicities, errors occur primarily through a single unwanted transition. This feature enables the design of fast three-qubit gates based on simple analytical pulse shapes that are engineered to minimize such errors. We show that a three-qubit ccz gate can be performed in 260 ns with fidelities exceeding 99.38%, or 99.99% with numerical optimization.",

author = "Edwin Barnes and Christian Arenz and Pitchford, {Alexander James Gordon} and Economou, {Sophia E.}",

year = "2017",

month = jul,

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doi = "10.1103/PhysRevB.96.024504",

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journal = "Physical Review B",

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T1 - Fast microwave-driven three-qubit gates for cavity-coupled superconducting qubits

AU - Barnes, Edwin

AU - Arenz, Christian

AU - Pitchford, Alexander James Gordon

AU - Economou, Sophia E.

PY - 2017/7/6

Y1 - 2017/7/6

N2 - Although single- and two-qubit gates are sufficient for universal quantum computation, single-shot three-qubit gates greatly simplify quantum error correction schemes and algorithms. We design fast, high-fidelity three-qubit entangling gates based on microwave pulses for transmon qubits coupled through a superconducting resonator. We show that when interqubit frequency differences are comparable to single-qubit anharmonicities, errors occur primarily through a single unwanted transition. This feature enables the design of fast three-qubit gates based on simple analytical pulse shapes that are engineered to minimize such errors. We show that a three-qubit ccz gate can be performed in 260 ns with fidelities exceeding 99.38%, or 99.99% with numerical optimization.

AB - Although single- and two-qubit gates are sufficient for universal quantum computation, single-shot three-qubit gates greatly simplify quantum error correction schemes and algorithms. We design fast, high-fidelity three-qubit entangling gates based on microwave pulses for transmon qubits coupled through a superconducting resonator. We show that when interqubit frequency differences are comparable to single-qubit anharmonicities, errors occur primarily through a single unwanted transition. This feature enables the design of fast three-qubit gates based on simple analytical pulse shapes that are engineered to minimize such errors. We show that a three-qubit ccz gate can be performed in 260 ns with fidelities exceeding 99.38%, or 99.99% with numerical optimization.

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DO - 10.1103/PhysRevB.96.024504

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Fast microwave-driven three-qubit gates for cavity-coupled superconducting qubits

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