On the moments of random quantum circuits and robust quantum complexity

Abstract

We prove new lower bounds on the growth of robust quantum circuit complexity -- the minimal number of gates Cδ(U) to approximate a unitary U up to an error of δ in operator norm distance. More precisely we show two bounds for random quantum circuits with local gates drawn from a subgroup of SU(4). First, for δ=(2-n), we prove a linear growth rate: Cδ≥ d/poly(n) for random quantum circuits on n qubits with d≤ 2n/2 gates. Second, for δ=(1), we prove a square-root growth of complexity: Cδ≥ d/poly(n) for all d≤ 2n/2. Finally, we provide a simple conjecture regarding the Fourier support of randomly drawn Boolean functions that would imply linear growth for constant δ. While these results follow from bounds on the moments of random quantum circuits, we do not make use of existing results on the generation of unitary t-designs. Instead, we bound the moments of an auxiliary random walk on the diagonal unitaries acting on phase states. In particular, our proof is comparably short and self-contained.