English

Single-step Quantum Simulation of Two Nucleons

Nuclear Theory 2025-12-16 v1 High Energy Physics - Theory Nuclear Experiment Quantum Physics

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 0p3/20p_{3/2} 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 MJ=0M_J=0 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.

Keywords

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)

R2 v1 2026-07-01T08:24:13.158Z