Power-efficient all-microwave manipulation of superconducting qubits with a fixed-frequency transmon coupler
ORAL
Abstract
The fixed-frequency transmon system is a promising candidate for practical quantum processor thanks to its long coherence time and low wiring cost. However, such architecture requires all-microwave entangling gates enabled with precise qubit-frequency allocation, which is a significant burden on design and fabrication. To address this issue, we propose and experimentally demonstrate a novel power-efficient all-microwave entangling gate using a fixed-frequency transmon coupler. This scheme, which tolerates relatively large frequency variations of qubits, executes a controlled-Z gate with 97.7(2)% average fidelity and eliminates residual ZZ interaction.
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Presenters
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Shotaro Shirai
Komaba Institute for Science, The University of Tokyo, KIS, The Univ. of Tokyo
Authors
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Shotaro Shirai
Komaba Institute for Science, The University of Tokyo, KIS, The Univ. of Tokyo
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Yuta Okubo
KIS, The Univ. of Tokyo
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Kohei Matsuura
Department of Applied Physics, The Univ. of Tokyo, University of Tokyo, Univ of Tokyo
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Alto Osada
The University of Tokyo, Japan, KIS, The Univ. of Tokyo
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Yasunobu Nakamura
RIKEN Center for Quantum Computing, RQC, RIKEN
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Atsushi Noguchi
The University of Tokyo, Japan, Komaba Institute for Science, The University of Tokyo, KIS, The Univ. of Tokyo