Related papers: High-fidelity gates with mid-circuit erasure conversion in a metastable neutral atom qubit

High-fidelity gates with mid-circuit erasure conversion in a metastable neutral atom qubit

URL: http://arxiv.org/abs/2305.05493v1
Date: Tue, 9 May 2023 14:46:06 GMT
Title: High-fidelity gates with mid-circuit erasure conversion in a metastable neutral atom qubit
Authors: Shuo Ma, Genyue Liu, Pai Peng, Bichen Zhang, Sven Jandura, Jahan Claes, Alex P. Burgers, Guido Pupillo, Shruti Puri, and Jeff D. Thompson
Abstract summary: We demonstrate a new neutral atom qubit, using the nuclear spin of a long-lived metastable state in $171$Yb. This work establishes metastable $171$Yb as a promising platform for realizing fault-tolerant quantum computing.
Score: 5.0016986564761865
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The development of scalable, high-fidelity qubits is a key challenge in quantum information science. Neutral atom qubits have progressed rapidly in recent years, demonstrating programmable processors and quantum simulators with scaling to hundreds of atoms. Exploring new atomic species, such as alkaline earth atoms, or combining multiple species can provide new paths to improving coherence, control and scalability. For example, for eventual application in quantum error correction, it is advantageous to realize qubits with structured error models, such as biased Pauli errors or conversion of errors into detectable erasures. In this work, we demonstrate a new neutral atom qubit, using the nuclear spin of a long-lived metastable state in ${}^{171}$Yb. The long coherence time and fast excitation to the Rydberg state allow one- and two-qubit gates with fidelities of 0.9990(1) and 0.980(1), respectively. Importantly, a significant fraction of all gate errors result in decays out of the qubit subspace, to the ground state. By performing fast, mid-circuit detection of these errors, we convert them into erasure errors; during detection, the induced error probability on qubits remaining in the computational space is less than $10^{-5}$. This work establishes metastable ${}^{171}$Yb as a promising platform for realizing fault-tolerant quantum computing.

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