Scalable error mitigation for noisy quantum circuits produces competitive expectation values

Noise in existing quantum processors only enables an approximation to ideal quantum computation. However, for the computation of expectation values, these approximations can be improved by error mitigation. This has been experimentally demonstrated in small systems but the scaling of these methods t...

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Bibliographic Details
Published inNature physics Vol. 19; no. 5; pp. 752 - 759
Main Authors Kim, Youngseok, Wood, Christopher J., Yoder, Theodore J., Merkel, Seth T., Gambetta, Jay M., Temme, Kristan, Kandala, Abhinav
Format Journal Article
LanguageEnglish
Published London Nature Publishing Group 01.05.2023
Subjects
Accuracy
Approximation
Circuits
Couplings
Error correction
Expected values
Fault tolerance
Gates (circuits)
Ising model
Lattices
Processors
Quantum computing
Qubits (quantum computing)
Spin dynamics
Tensors
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Summary:Noise in existing quantum processors only enables an approximation to ideal quantum computation. However, for the computation of expectation values, these approximations can be improved by error mitigation. This has been experimentally demonstrated in small systems but the scaling of these methods to larger circuit volumes remains unknown. Here we demonstrate the utility of zero-noise extrapolation for practically relevant quantum circuits using up to 26 qubits, circuit depths of 120 and 1,080 CNOT gates. We study the scaling of the method for canonical examples of product states and entangling Clifford circuits of increasing size, and extend it to simulating the quench dynamics of two-dimensional Ising spin lattices with varying couplings. These experiments reveal that the accuracy of physically relevant observables after error mitigation substantially exceeds previously expected values. Furthermore, we show that the efficacy of error mitigation is greatly enhanced by additional error suppression techniques and native gate decomposition that reduce the circuit time. By combining these methods, the accuracy of our quantum simulation surpasses the classical approximations obtained from an established tensor network method. These results establish the potential of a useful quantum advantage using noisy, digital quantum processors.A technique called error mitigation can significantly improve the performance of large-scale quantum computations on near-term devices without the significant resource overheard of fault-tolerant quantum error correction.
ISSN:1745-2473
1745-2481
DOI:10.1038/s41567-022-01914-3