Quantum Information Scrambling Through a High-Complexity Operator Mapping
Abstract
Quantum information scrambling has attracted much attention amid the effort to reconcile the conflict between quantum-mechanical unitarity and the thermalizaiton-irreversibility in many-body systems. Here we propose an unconventional mechanism to generate quantum information scrambling through a high-complexity mapping from logical to physical degrees-of-freedom that hides the logical information into non-separable many-body-correlations. Corresponding to this mapping, we develop an algorithm to efficiently sample a Slater-determinant wavefunction and compute all physical observables in dynamics with a polynomial cost in system-size. The system shows information scrambling in the quantum many-body Hilbert space characterized by the spreading of Hamming-distance. At late time, we find emergence of classical diffusion dynamics in this quantum many-body system. We establish that the operator-mapping enabled growth in out-of-time-order-correlator exhibits exponential-scrambling behavior. The quantum information-hiding mapping approach may shed light on the understanding of fundamental connections among computational complexity, information scrambling and quantum thermalization.
Cite
@article{arxiv.1806.00472,
title = {Quantum Information Scrambling Through a High-Complexity Operator Mapping},
author = {Xiaopeng Li and Guanyu Zhu and Muxin Han and Xin Wang},
journal= {arXiv preprint arXiv:1806.00472},
year = {2019}
}
Comments
8 pages, 4 figures, published version