High-fidelity Parametric Entangling Gates for Superconducting Quantum Processors
ORAL
Abstract
Parametrically-activated gates driven by a flux-tunable coupler are a promising approach to engineering fast, high-fidelity entanglement between fixed-frequency transmons. By selecting the proper resonance condition, we can generate both XY-like and ZZ-like interactions, improving the expressiveness of hardware native gatesets in superconducting quantum processors. In this work, we realize and benchmark high-fidelity iSWAP and CZ gates between qubits. We then demonstrate how these techniques can be extended to 3-level qutrit systems to engineer a two-qutrit parametric CZ gate.
* This material was funded by the U.S. Department of Energy, Office of Science, Office of Advanced Scientific Computing Research Quantum Testbed Program under contract DE-AC02-05CH11231.
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Presenters
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Larry Chen
University of California, Berkeley
Authors
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Larry Chen
University of California, Berkeley
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Kan-Heng Lee
Lawrence Berkeley National Laboratory
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Noah Goss
University of California Berkeley, University of California, Berkeley
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Ziqi (Candice) Kang
University of California, Berkeley
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Ravi K Naik
Lawrence Berkeley National Laboratory
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David I Santiago
Lawrence Berkeley National Laboratory
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Irfan Siddiqi
University of California, Berkeley