Related papers: Exact analytic toolbox for quantum dynamics with tunable noise strength

Exact analytic toolbox for quantum dynamics with tunable noise strength

URL: http://arxiv.org/abs/2410.07321v1
Date: Wed, 9 Oct 2024 18:00:01 GMT
Title: Exact analytic toolbox for quantum dynamics with tunable noise strength
Authors: Mert Okyay, Oliver Hart, Rahul Nandkishore, Aaron J. Friedman,
Abstract summary: We introduce a framework that allows for the exact analytic treatment of quantum dynamics subject to coherent noise. Averaging over the ensemble of ''noisy'' Hamiltonians produces an effective quantum channel. Key advantages of our approach include the ability to access exact analytic results for any $N$ and the ability to tune to the noise-free limit.
Score: 0.23301643766310368
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We introduce a framework that allows for the exact analytic treatment of quantum dynamics subject to coherent noise. The noise is modeled via unitary evolution under a Hamiltonian drawn from a random-matrix ensemble for arbitrary Hilbert-space dimension $N$. While the methods we develop apply to generic such ensembles with a notion of rotation invariance, we focus largely on the Gaussian unitary ensemble (GUE). Averaging over the ensemble of ''noisy'' Hamiltonians produces an effective quantum channel, the properties of which are analytically calculable and determined by the spectral form factors of the relevant ensemble. We compute spectral form factors of the GUE exactly for any finite $N$, along with the corresponding GUE quantum channel, and its variance. Key advantages of our approach include the ability to access exact analytic results for any $N$ and the ability to tune to the noise-free limit (in contrast, e.g., to the Haar ensemble), and analytic access to moments beyond the variance. We also highlight some unusual features of the GUE channel, including the nonmonotonicity of the coefficients of various operators as a function of noise strength and the failure to saturate the Haar-random limit, even with infinite noise strength.

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