Experimental progress towards a bias-preserving CNOT gate between two Kerr-cat qubits
ORAL
Abstract
The Kerr-cat qubit, implemented via a driven SNAIL in circuit QED, is a particularly promising candidate for hardware-efficient quantum error correction due to its noise bias [1, 2]. While single-qubit performance is steadily improving [3, 4], a bias-preserving two-qubit gate is required to harvest the full potential of the noise bias for improved error correction thresholds [2].
A theoretical proposal offers a solution [5]—a fast, high-fidelity & bias-preserving CNOT gate can be realized parametrically in the SNAIL implementation. In this talk, we will present the operation of two coupled Kerr-cat qubits, and I report on our experimental progress toward realizing the bias-preserving CNOT gate. Importantly, our approach relies on the native four-wave mixing capabilities of the SNAIL, eliminating the need for extra coupling elements.
A theoretical proposal offers a solution [5]—a fast, high-fidelity & bias-preserving CNOT gate can be realized parametrically in the SNAIL implementation. In this talk, we will present the operation of two coupled Kerr-cat qubits, and I report on our experimental progress toward realizing the bias-preserving CNOT gate. Importantly, our approach relies on the native four-wave mixing capabilities of the SNAIL, eliminating the need for extra coupling elements.
* Work supported by: ARO, AFOSR, NSF, DOE and YINQE
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Publication: [1] Puri et al., npj Quantum Information 2017; [2] Darmawan et al., PRX Quantum 2021; [3] Grimm, Frattini et al., Nature 2020; [4] Venkatraman, Cortiñas et al., arXiv 2023; [5] Puri et al., Science Advances 2020
Presenters
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Max K Schaefer
Yale University
Authors
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Max K Schaefer
Yale University
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Rodrigo G Cortinas
Yale University
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Nicholas E Frattini
JILA and NIST
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Qile Su
Yale University
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Shruti Puri
Yale University
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Michel H Devoret
Yale University