English

Designing quantum technologies with a quantum computer

Quantum Physics 2026-01-30 v1 Materials Science

Abstract

Interacting spin systems in solids underpin a wide range of quantum technologies, from quantum sensors and single-photon sources to spin-defect-based quantum registers and processors. We develop a quantum-computer-aided framework for simulating such devices using a general electron spin resonance Hamiltonian incorporating zero-field splitting, the Zeeman effect, hyperfine interactions, dipole-dipole spin-spin terms, and electron-phonon decoherence. Within this model, we combine Gray-encoded qudit-to-qubit mappings, qubit-wise commuting aggregation, and a multi-reference selected quantum Krylov fast-forwarding (sQKFF) hybrid algorithm to access long-time dynamics while remaining compatible with NISQ and early fault-tolerant hardware constraints. Numerical simulations demonstrate the computation of autocorrelation functions up to 100\sim100 ns, together with microwave absorption spectra and the 1\ell_1-norm of coherence, achieving 18-30%\% reductions in gate counts and circuit depth for Trotterized time-evolution circuits compared to unoptimized implementations. Using the nitrogen vacancy center in diamond as a testbed, we benchmark the framework against classical simulations and identify the reference-state selection in sQKFF as the primary factor governing accuracy at fixed hardware cost. This methodology provides a flexible blueprint for using quantum computers to design, compare, and optimize solid-state spin-qubit technologies under experimentally realistic conditions.

Keywords

Cite

@article{arxiv.2601.22091,
  title  = {Designing quantum technologies with a quantum computer},
  author = {Juan Naranjo and Thi Ha Kyaw and Gaurav Saxena and Kevin Ferreira and Jack S. Baker},
  journal= {arXiv preprint arXiv:2601.22091},
  year   = {2026}
}

Comments

13 pages, 6 figures, 2 tables

R2 v1 2026-07-01T09:26:21.639Z