Efficient unitary designs with nearly time-independent Hamiltonian dynamics

Abstract

We provide new constructions of unitary t-designs for general t on one qudit and N qubits, and propose a design Hamiltonian, a random Hamiltonian of which dynamics always forms a unitary design after a threshold time, as a basic framework to investigate randomising time evolution in quantum many-body systems. The new constructions are based on recently proposed schemes of repeating random unitaires diagonal in mutually unbiased bases. We first show that, if a pair of the bases satisfies a certain condition, the process on one qudit approximately forms a unitary t-design after O(t) repetitions. We then construct quantum circuits on N qubits that achieve unitary t-designs for t = o(N1/2) using O(t N2) gates, improving the previous result using O(t10N2) gates in terms of t. Based on these results, we present a design Hamiltonian with periodically changing two-local spin-glass-type interactions, leading to fast and relatively natural realisations of unitary designs in complex many-body systems.