Tuning quantum magic of pure quantum chaotic states with a gravity dual
Abstract
Quantum magic is a fundamental resource that quantifies to what extent quantum states can be efficiently simulated on a classical computer. We study it for states constructed from the Sachdev-Ye-Kitaev (SYK) Hamiltonian with N Majoranas by the fermionic anti-flatness (FAF). We show analytically that, in the large N limit, the quantum magic of pure Kourkoulou-Maldacena (KM) states, dual to a quantum black hole with an end-of-world particle behind the horizon, is linear in N with a slope, depending on the black hole temperature, that can be tuned between zero and 1/2. By contrast, the FAF of Gaussian states evolved in real time with the SYK Hamitonian approaches ≈ N/2 exponentially at a rate given by a multiple of the leading Ruelle-Pollicot resonance. Subleading corrections in N for SYK energy eigenstates, computed numerically for N ≤ 54 by combining Krylov subspace with GPU acceleration techniques, decay exponentially with N, but power-law if the SYK couplings are sparsified, and are order of magnitude larger for states close to the ground state, a region with an established gravity analogue. Our results offer new insights about the relation between quantum information, quantum chaos and low-dimension quantum gravity.
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