Single Flux Quantum-Based Digital Control of Superconducting Qubits in a Multi-Chip Module
Single flux quantum (SFQ) digital logic has been proposed for the scalable control of next-generation superconducting-qubit arrays. In the initial implementation, SFQ-based gate fidelity was limited by quasiparticle (QP) poisoning induced by the dissipative on-chip SFQ driver circuit. In this work,...
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| Published in: | PRX quantum Vol. 4 |
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| Main Authors: | , , , , , , , , , , , , , , , , , |
| Format: | Journal Article |
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American Physical Society (APS)
24-07-2023
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| Abstract | Single flux quantum (SFQ) digital logic has been proposed for the scalable control of next-generation superconducting-qubit arrays. In the initial implementation, SFQ-based gate fidelity was limited by quasiparticle (QP) poisoning induced by the dissipative on-chip SFQ driver circuit. In this work, we introduce a multichip-module architecture to suppress phonon-mediated QP poisoning. Here, the SFQ elements and qubits are fabricated on separate chips that are joined with In-bump bonds. We use interleaved randomized benchmarking to characterize the fidelity of SFQ-based gates and we demonstrate an error per Clifford gate of 1.2(1)%, an order-of-magnitude reduction over the gate error achieved in the initial realization of SFQ-based qubit control. We use purity benchmarking to quantify the contribution of incoherent error at 0.96(2)%; we attribute this error to photon-mediated QP poisoning mediated by the resonant millimeter-wave antenna modes of the qubit and SFQ-qubit coupler. We anticipate that a straightforward redesign of the SFQ driver circuit to limit the bandwidth of the SFQ pulses will eliminate this source of infidelity, allowing SFQ-based gates with error approaching approximate known theoretical limits, of order 0.1% for resonant sequences and 0.01% for more complex pulse sequences involving variable pulse-to-pulse separation. |
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| AbstractList | Single flux quantum (SFQ) digital logic has been proposed for the scalable control of next-generation superconducting-qubit arrays. In the initial implementation, SFQ-based gate fidelity was limited by quasiparticle (QP) poisoning induced by the dissipative on-chip SFQ driver circuit. In this work, we introduce a multichip-module architecture to suppress phonon-mediated QP poisoning. Here, the SFQ elements and qubits are fabricated on separate chips that are joined with In-bump bonds. We use interleaved randomized benchmarking to characterize the fidelity of SFQ-based gates and we demonstrate an error per Clifford gate of 1.2(1)%, an order-of-magnitude reduction over the gate error achieved in the initial realization of SFQ-based qubit control. We use purity benchmarking to quantify the contribution of incoherent error at 0.96(2)%; we attribute this error to photon-mediated QP poisoning mediated by the resonant millimeter-wave antenna modes of the qubit and SFQ-qubit coupler. We anticipate that a straightforward redesign of the SFQ driver circuit to limit the bandwidth of the SFQ pulses will eliminate this source of infidelity, allowing SFQ-based gates with error approaching approximate known theoretical limits, of order 0.1% for resonant sequences and 0.01% for more complex pulse sequences involving variable pulse-to-pulse separation. |
| Author | McDermott, R. Lucas, T. Dodge, K. Opremcak, A. Liu, C. H. Olaya, D. Rafferty, O. Iaia, V. Ballard, A. McBroom, T. DuBois, J. L. Schmidt, D. R. Plourde, B. L. T. Benz, S. P. Ullom, J. Biesecker, J. Hopkins, P. F. Patel, S. |
| Author_xml | – sequence: 1 fullname: Liu, C. H. organization: University of Wisconsin, Madison, WI (United States) – sequence: 2 fullname: Ballard, A. organization: Syracuse University, NY (United States) – sequence: 3 fullname: Olaya, D. organization: National Inst. of Standards and Technology (NIST), Boulder, CO (United States); University of Colorado, Boulder, CO (United States) – sequence: 4 fullname: Schmidt, D. R. organization: National Inst. of Standards and Technology (NIST), Boulder, CO (United States) – sequence: 5 fullname: Biesecker, J. organization: National Inst. of Standards and Technology (NIST), Boulder, CO (United States) – sequence: 6 fullname: Lucas, T. organization: National Inst. of Standards and Technology (NIST), Boulder, CO (United States) – sequence: 7 fullname: Ullom, J. organization: National Inst. of Standards and Technology (NIST), Boulder, CO (United States); University of Colorado, Boulder, CO (United States) – sequence: 8 fullname: Patel, S. organization: University of Wisconsin, Madison, WI (United States) – sequence: 9 fullname: Rafferty, O. organization: University of Wisconsin, Madison, WI (United States) – sequence: 10 fullname: Opremcak, A. organization: University of Wisconsin, Madison, WI (United States) – sequence: 11 fullname: Dodge, K. organization: Syracuse University, NY (United States) – sequence: 12 fullname: Iaia, V. organization: Syracuse University, NY (United States) – sequence: 13 fullname: McBroom, T. organization: Syracuse University, NY (United States) – sequence: 14 fullname: DuBois, J. L. organization: Lawrence Livermore National Laboratory (LLNL), Livermore, CA (United States) – sequence: 15 fullname: Hopkins, P. F. organization: National Inst. of Standards and Technology (NIST), Boulder, CO (United States) – sequence: 16 fullname: Benz, S. P. organization: National Inst. of Standards and Technology (NIST), Boulder, CO (United States) – sequence: 17 fullname: Plourde, B. L. T. organization: Syracuse University, NY (United States) – sequence: 18 fullname: McDermott, R. organization: University of Wisconsin, Madison, WI (United States) |
| BackLink | https://www.osti.gov/biblio/1992163$$D View this record in Osti.gov |
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| Snippet | Single flux quantum (SFQ) digital logic has been proposed for the scalable control of next-generation superconducting-qubit arrays. In the initial... |
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| SubjectTerms | CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY quantum circuits quantum control superconducting devices superconducting qubits |
| Title | Single Flux Quantum-Based Digital Control of Superconducting Qubits in a Multi-Chip Module |
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