Single-step Quantum Simulation of Two Nucleons
Abstract
Quantum computing offers a scalable approach to solving the nuclear shell model, a highly complex and exponentially scaled many-body problem. This work presents a numerical simulation of the subspace search variational quantum eigensolver (SSVQE) combined with an adaptive derivative-assembles pseudo-trotter (ADAPT) ansatz to obtain the low-lying states of any nuclear system in a single optimization run. As an example, we apply this method in this work to a trivial identical nucleon system, two nucleons in the orbital, mapped to 4 qubits depicting m-scheme single-particle states including a surface delta effective interaction using the Jordan-Wigner transformation. The ADAPT-SSVQE algorithm, by utilizing a symmetry-preserving double-excitation ADAPT operator pool, uniquely optimizes a weighted energy sum, forcing the simultaneous convergence of two lowest states within the total angular momentum subspace. We demonstrate the accuracy of the method by benchmarking against the exact diagonalization, confirming its potential for probing nuclear structure and pairing phenomena on current and near-future quantum devices without requiring multi-step procedure for excited states.
Cite
@article{arxiv.2512.12798,
title = {Single-step Quantum Simulation of Two Nucleons},
author = {Bhoomika Maheshwari and Paul Stevenson and P. Van Isacker},
journal= {arXiv preprint arXiv:2512.12798},
year = {2025}
}
Comments
To Appear in Acta Physica Polonica B (Special Issue dedicated to Mazurian Lakes Conference 2025)