Orbital-optimized pair-correlated electron simulations on trapped-ion quantum computers
Abstract
Variational quantum eigensolvers (VQE) are among the most promising approaches for solving electronic structure problems on near-term quantum computers. A critical challenge for VQE in practice is that one needs to strike a balance between the expressivity of the VQE ansatz versus the number of quantum gates required to implement the ansatz, given the reality of noisy quantum operations on near-term quantum computers. In this work, we consider an orbital-optimized pair-correlated approximation to the unitary coupled cluster with singles and doubles (uCCSD) ansatz and report a highly efficient quantum circuit implementation for trapped-ion architectures. We show that orbital optimization can recover significant additional electron correlation energy without sacrificing efficiency through measurements of low-order reduced density matrices (RDMs). In the dissociation of small molecules, the method gives qualitatively accurate predictions in the strongly-correlated regime when running on noise-free quantum simulators. On IonQ's Harmony and Aria trapped-ion quantum computers, we run end-to-end VQE algorithms with up to 12 qubits and 72 variational parameters - the largest full VQE simulation with a correlated wave function on quantum hardware. We find that even without error mitigation techniques, the predicted relative energies across different molecular geometries are in excellent agreement with noise-free simulators.
Cite
@article{arxiv.2212.02482,
title = {Orbital-optimized pair-correlated electron simulations on trapped-ion quantum computers},
author = {Luning Zhao and Joshua Goings and Kenneth Wright and Jason Nguyen and Jungsang Kim and Sonika Johri and Kyujin Shin and Woomin Kyoung and Johanna I. Fuks and June-Koo Kevin Rhee and Young Min Rhee},
journal= {arXiv preprint arXiv:2212.02482},
year = {2023}
}