Improved spectral gaps for random quantum circuits: large local dimensions and all-to-all interactions

Abstract

Random quantum circuits are a central concept in quantum information theory with applications ranging from demonstrations of quantum computational advantage to descriptions of scrambling in strongly-interacting systems and black holes. The utility of random quantum circuits in these settings stems from their ability to rapidly generate quantum pseudo-randomness. In a seminal paper by Brand\~ao, Harrow, and Horodecki, it was proven that the t-th moment operator of local random quantum circuits on n qudits with local dimension q has a spectral gap of at least (n-1t-5-3.1/(q)), which implies that they are efficient constructions of approximate unitary designs. As a first result, we use Knabe bounds for the spectral gaps of frustration-free Hamiltonians to show that 1D random quantum circuits have a spectral gap scaling as (n-1), provided that t is small compared to the local dimension: t2≤ O(q). This implies a (nearly) linear scaling of the circuit depth in the design order t. Our second result is an unconditional spectral gap bounded below by (n-1-1(n) t-α(q)) for random quantum circuits with all-to-all interactions. This improves both the n and t scaling in design depth for the non-local model. We show this by proving a recursion relation for the spectral gaps involving an auxiliary random walk. Lastly, we solve the smallest non-trivial case exactly and combine with numerics and Knabe bounds to improve the constants involved in the spectral gap for small values of t.