Universal robust quantum gates by geometric correspondence of noisy quantum dynamics

• URL: http://arxiv.org/abs/2210.14521v3
• Date: Tue, 7 Nov 2023 23:45:31 GMT
• Title: Universal robust quantum gates by geometric correspondence of noisy quantum dynamics
• Authors: Yong-Ju Hai, Junning Li, Junkai Zeng, and Xiu-Hao Deng
• Abstract summary: We develop a theory to capture quantum dynamics due to various noises graphically, obtaining the quantum erroneous evolution diagrams (QEED) We then develop a protocol to engineer a universal set of single- and two-qubit robust gates that correct the generic errors. Our approach offers new insights into the geometric aspects of noisy quantum dynamics and several advantages over existing methods.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Exposure to noises is a major obstacle for processing quantum information, but noises don't necessarily induce errors. Errors on the quantum gates could be suppressed via robust quantum control techniques. But understanding the genesis of errors and finding a universal treatment remains grueling. To resolve this issue, we develop a geometric theory to capture quantum dynamics due to various noises graphically, obtaining the quantum erroneous evolution diagrams (QEED). Our theory provides explicit necessary and sufficient criteria for robust control Hamiltonian and quantitative geometric metrics of the gate error. We then develop a protocol to engineer a universal set of single- and two-qubit robust gates that correct the generic errors. Our numerical simulation shows gate fidelities above $99.99\%$ over a broad region of noise strength using simplest and smooth pulses for arbitrary gate time. Our approach offers new insights into the geometric aspects of noisy quantum dynamics and several advantages over existing methods, including the treatment of arbitrary noises, independence of system parameters, scalability, and being friendly to experiments.

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