English

Random quantum circuits anti-concentrate in log depth

Quantum Physics 2022-03-08 v2 Statistical Mechanics Strongly Correlated Electrons

Abstract

We consider quantum circuits consisting of randomly chosen two-local gates and study the number of gates needed for the distribution over measurement outcomes for typical circuit instances to be anti-concentrated, roughly meaning that the probability mass is not too concentrated on a small number of measurement outcomes. Understanding the conditions for anti-concentration is important for determining which quantum circuits are difficult to simulate classically, as anti-concentration has been in some cases an ingredient of mathematical arguments that simulation is hard and in other cases a necessary condition for easy simulation. Our definition of anti-concentration is that the expected collision probability, that is, the probability that two independently drawn outcomes will agree, is only a constant factor larger than if the distribution were uniform. We show that when the 2-local gates are each drawn from the Haar measure (or any two-design), at least Ω(nlog(n))\Omega(n \log(n)) gates (and thus Ω(log(n))\Omega(\log(n)) circuit depth) are needed for this condition to be met on an nn qudit circuit. In both the case where the gates are nearest-neighbor on a 1D ring and the case where gates are long-range, we show O(nlog(n))O(n \log(n)) gates are also sufficient, and we precisely compute the optimal constant prefactor for the nlog(n)n \log(n). The technique we employ relies upon a mapping from the expected collision probability to the partition function of an Ising-like classical statistical mechanical model, which we manage to bound using stochastic and combinatorial techniques.

Keywords

Cite

@article{arxiv.2011.12277,
  title  = {Random quantum circuits anti-concentrate in log depth},
  author = {Alexander M. Dalzell and Nicholas Hunter-Jones and Fernando G. S. L. Brandão},
  journal= {arXiv preprint arXiv:2011.12277},
  year   = {2022}
}

Comments

46 pages, 7 figures. v2: Reformatted, fixed typos, added figure 3

R2 v1 2026-06-23T20:29:01.305Z