Universal quantum circuits for quantum chemistry
Abstract
Universal gate sets for quantum computing have been known for decades, yet no universal gate set has been proposed for particle-conserving unitaries, which are the operations of interest in quantum chemistry. In this work, we show that controlled single-excitation gates in the form of Givens rotations are universal for particle-conserving unitaries. Single-excitation gates describe an arbitrary rotation on the two-qubit subspace spanned by the states , while leaving other states unchanged -- a transformation that is analogous to a single-qubit rotation on a dual-rail qubit. The proof is constructive, so our result also provides an explicit method for compiling arbitrary particle-conserving unitaries. Additionally, we describe a method for using controlled single-excitation gates to prepare an arbitrary state of a fixed number of particles. We derive analytical gradient formulas for Givens rotations as well as decompositions into single-qubit and CNOT gates. Our results offer a unifying framework for quantum computational chemistry where every algorithm is a unique recipe built from the same universal ingredients: Givens rotations.
Cite
@article{arxiv.2106.13839,
title = {Universal quantum circuits for quantum chemistry},
author = {Juan Miguel Arrazola and Olivia Di Matteo and Nicolás Quesada and Soran Jahangiri and Alain Delgado and Nathan Killoran},
journal= {arXiv preprint arXiv:2106.13839},
year = {2022}
}
Comments
11 pages, 12 figures