Time complexity in preparing metrologically useful quantum states
Abstract
We investigate the fundamental time complexity, as constrained by Lieb-Robinson bounds, for preparing entangled states useful in quantum metrology. We relate the minimum time to the Quantum Fisher Information (FQ) for a system of N quantum spins on a d-dimensional lattice with 1/rα interactions with r being the distance between two interacting spins. We focus on states with FQ N1+γ where γ ∈ (0,1], i.e., scaling from the standard quantum limit to the Heisenberg limit. For short-range interactions (α > 2d+1), we prove the minimum time t scales as t Lγ, where L N1/d. For long-range interactions, we find a hierarchy of possible speedups: t Lγ(α-2d) for 2d < α < 2d+1, t L for (2-γ)d < α < 2d, and t may even vanish algebraically in 1/L for α < (2-γ)d. These bounds extend to the minimum circuit depth required for state preparation, assuming two-qubit gate speeds scale as 1/rα. We further show that these bounds are saturable, up to sub-polynomial corrections, for all α at the Heisenberg limit (γ=1) and for α > (2-γ)d when γ<1. Our results establish a benchmark for the time-optimality of protocols that prepare metrologically useful quantum states.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.