English

Optimal quantum spatial search with one-dimensional long-range interactions

Quantum Physics 2021-06-18 v2

Abstract

Continuous-time quantum walks can be used to solve the spatial search problem, which is an essential component for many quantum algorithms that run quadratically faster than their classical counterpart, in O(n)\mathcal O(\sqrt n) time for nn entries. However the capability of models found in nature is largely unexplored - e.g., in one dimension only nearest-neighbour Hamiltonians have been considered so far, for which the quadratic speedup does not exist. Here, we prove that optimal spatial search, namely with O(n)\mathcal O(\sqrt n) run time and large fidelity, is possible in one-dimensional spin chains with long-range interactions that decay as 1/rα1/r^\alpha with distance rr. In particular, near unit fidelity is achieved for α1\alpha\approx 1 and, in the limit nn\to\infty, we find a continuous transition from a region where optimal spatial search does exist (α<1.5\alpha<1.5) to where it does not (α>1.5\alpha>1.5). Numerically, we show that spatial search is robust to dephasing noise and that, for realistic conditions, α1.2\alpha \lesssim 1.2 should be sufficient to demonstrate optimal spatial search experimentally with near unit fidelity.

Keywords

Cite

@article{arxiv.2010.04299,
  title  = {Optimal quantum spatial search with one-dimensional long-range interactions},
  author = {Dylan Lewis and Asmae Benhemou and Natasha Feinstein and Leonardo Banchi and Sougato Bose},
  journal= {arXiv preprint arXiv:2010.04299},
  year   = {2021}
}

Comments

16 pages, 6 figures; accepted version

R2 v1 2026-06-23T19:11:32.005Z