English

Random unitaries in extremely low depth

Quantum Physics 2025-01-07 v2 Strongly Correlated Electrons Computational Complexity Information Theory math.IT

Abstract

We prove that random quantum circuits on any geometry, including a 1D line, can form approximate unitary designs over nn qubits in logn\log n depth. In a similar manner, we construct pseudorandom unitaries (PRUs) in 1D circuits in poly(logn)\text{poly}(\log n) depth, and in all-to-all-connected circuits in poly(loglogn)\text{poly}(\log \log n) depth. In all three cases, the nn 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 logn\log n-sized or poly(logn)\text{poly}(\log n)-sized patches of qubits to form a global random unitary on all nn qubits. In the case of designs, the local unitaries are drawn from existing constructions of approximate unitary kk-designs, and hence also inherit an optimal scaling in kk. 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

R2 v1 2026-06-28T17:35:53.501Z