Recipes for the Digital Quantum Simulation of Lattice Spin Systems

TL;DR

This paper presents methods and resource estimates for digital quantum simulation of lattice spin systems, optimizing circuit design and execution strategies for efficient quantum simulations.

Contribution

It introduces new quantum circuit constructions and resource estimates for simulating lattice spin systems with improved efficiency and parallelization techniques.

Findings

Resource estimates for gate count and simulation time

Circuit constructions for first- and higher-order Trotter expansions

Potential impact of scaled gates on simulation efficiency

Abstract

We describe methods to construct digital quantum simulation algorithms for quantum spin systems on a regular lattice with local interactions. In addition to tools such as the Trotter-Suzuki expansion and graph coloring, we also discuss the efficiency gained by parallel execution of an extensive number of commuting terms. We provide resource estimates and quantum circuit elements for the most important cases and classes of spin systems. As resource estimates we indicate the total number of gates $N$ and simulation time $T$, expressed in terms of the number $n$ of spin 1/2 lattice sites (qubits), target accuracy $\epsilon$, and simulated time $t$. We provide circuit constructions that realize the simulation time $T^{(1)}\propto nt^2/\epsilon$ and $T^{(2q)}\propto t^{1+\eta}n^\eta/\epsilon^\eta$ for arbitrarily small $\eta=1/2q$ for the first-order and higher-order Trotter expansions. We also discuss the potential impact of scaled gates, which have not yet been fully explored.