High-precision Quantum Phase Estimation on a Trapped-ion Quantum Computer

TL;DR

This paper demonstrates high-precision quantum phase estimation for molecular hydrogen on a 56-qubit trapped-ion quantum computer, achieving unprecedented accuracy with limited shots and discussing its potential as a benchmark for near-term quantum devices.

Contribution

It introduces a simple benchmarking method using multi-ancilla quantum phase estimation for small chemical systems, enabling high-precision results on larger qubit circuits.

Findings

Achieved 50-bit precision in ground state energy of H2

Produced results exceeding chemical accuracy with limited shots

Demonstrated feasibility of high-precision quantum chemistry on trapped-ion hardware

Abstract

Emergent quantum computing technologies are widely expected to provide novel approaches in the simulation of quantum chemistry. Despite rapid improvements in the scale and fidelity of quantum computers, high resource requirements make the execution of quantum chemistry experiments challenging. Typical experiments are limited in the number of qubits used, incur a substantial shot cost, or require complex architecture-specific optimization and error mitigation techniques. In this paper, we propose a conceptually simple benchmarking approach involving the use of multi-ancilla quantum phase estimation. Our approach is restricted to very small chemical systems, and does not scale favorably beyond molecular systems that can be described with $2$ qubits; however, this restriction allows us to generate circuits that scale quadratically in gate count with the number of qubits in the readout register. This enables the execution of quantum chemistry circuits that act on many qubits, while producing meaningful results with limited shot counts. We use this technique (with $200$ shots per experiment) to calculate the ground state energy of molecular hydrogen to $50$ bits of precision ($8.9 \times 10^{-16}$ hartree) on a $56$-qubit trapped-ion quantum computer, negating Trotter error. Including Trotter error, we obtain between $32$ and $36$ bits of precision ($1.5 * 10^{-10}$ and $6.0 * 10^{-11}$ hartree respectively), vastly exceeding chemical accuracy ($1.6 * 10^{-3}$ hartree) against Full Configuration Interaction. We consider application of the approach to deeper circuits, and discuss potential as a benchmark task for near-term quantum devices.