Random unitaries in extremely low depth
Abstract
We prove that random quantum circuits on any geometry, including a 1D line, can form approximate unitary designs over qubits in depth. In a similar manner, we construct pseudorandom unitaries (PRUs) in 1D circuits in depth, and in all-to-all-connected circuits in depth. In all three cases, the dependence is optimal and improves exponentially over known results. These shallow quantum circuits have low complexity and create only short-range entanglement, yet are indistinguishable from unitaries with exponential complexity. Our construction glues local random unitaries on -sized or -sized patches of qubits to form a global random unitary on all qubits. In the case of designs, the local unitaries are drawn from existing constructions of approximate unitary -designs, and hence also inherit an optimal scaling in . In the case of PRUs, the local unitaries are drawn from existing PRU constructions. Applications of our results include proving that classical shadows with 1D log-depth Clifford circuits are as powerful as those with deep circuits, demonstrating superpolynomial quantum advantage in learning low-complexity physical systems, and establishing quantum hardness for recognizing phases of matter with topological order.
Keywords
Cite
@article{arxiv.2407.07754,
title = {Random unitaries in extremely low depth},
author = {Thomas Schuster and Jonas Haferkamp and Hsin-Yuan Huang},
journal= {arXiv preprint arXiv:2407.07754},
year = {2025}
}
Comments
12 pages, 6 figures + 48-page appendix; v2: simplified proofs, added new results and updated refs