It is not possible, using standard lattice techniques in Euclidean space, to calculate the complete fermionic spectrum of a quantum field theory. Algorithms running on quantum computers have the potential to access the theory with real-time evolution, enabling a direct computation. As a testing ground we consider the 1 + 1-dimensional Schwinger model with the presence of a {\theta} term using a staggered fermions discretization. We study the convergence properties of two different algorithms - adiabatic evolution and the Quantum Approximate Optimization Algorithm - with an emphasis on their cost in terms of CNOT gates. This is crucial to understand the feasibility of these algorithms, because calculations on near-term quantum devices depend on their rapid convergence. We also propose a blocked algorithm that has the first indications of a better scaling behavior with the dimensionality of the problem.
@article{arxiv.2109.11859,
title = {Quantum State Preparation for the Schwinger Model},
author = {Giovanni Pederiva and Alexei Bazavov and Brandon Henke and Leon Hostetler and Dean Lee and Huey-Wen Lin and Andrea Shindler},
journal= {arXiv preprint arXiv:2109.11859},
year = {2021}
}
Comments
9 pages, 2 figures, 38th International Symposium on Lattice Field Theory, LATTICE2021 26th-30th July, 2021 Zoom/Gather@Massachusetts Institute of Technology