Quantum Simulation of the Sachdev-Ye-Kitaev Model by Asymmetric Qubitization

Abstract

We show that one can quantum simulate the dynamics of a Sachdev-Ye-Kitaev model with N Majorana modes for time t to precision ε with gate complexity O(N7/2 t + N5/2 t \, polylog(N/ ε)). In addition to scaling sublinearly in the number of Hamiltonian terms, this gate complexity represents an exponential improvement in 1/ε and large polynomial improvement in N and t over prior state-of-the-art algorithms which scale as O(N10 t2 / ε). Our approach involves a variant of the qubitization technique in which we encode the Hamiltonian H as an asymmetric projection of a signal oracle U onto two different signal states prepared by state oracles, A0 A and B 0 B, such that H = B UA. Our strategy for applying this method to the Sachdev-Ye-Kitaev model involves realizing B using only Hadamard gates and realizing A as a random quantum circuit.