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Split-Evolution Quantum Phase Estimation for Particle-Conserving Hamiltonians

Quantum Physics 2026-04-17 v1 Computational Physics

Abstract

We present a hardware demonstration and resource analysis of split-evolution quantum phase estimation (SE-QPE) on a Quantinuum System Model H2 quantum computer. SE-QPE is a modification to canonical QPE for particle-conserving Hamiltonians in which controlled time evolution is replaced by CSWAP-based interference between a target register and a reference register. For factorizations of time evolution with a shared eigenbasis, SE-QPE preserves the phase-register outcome distribution of canonical QPE and, unlike with compute--uncompute substitutions, it remains compatible with non-exact eigenstates. The substitution removes controlled-simulation overhead and enables parallel evolution on two registers, reducing the depth of each phase-kickback block. Resource analysis for Trotterized double-factorized chemistry Hamiltonians shows that the substitution becomes increasingly favorable at higher phase powers, as such combining QPE and SE-QPE implementations can be a useful option. Over a range of FeMoco active spaces, SE-QPE reduces time evolution resources, with asymptotic reductions of about 33% in CX count, 25% in TT count, and an asymptotic depth ratio of 3/N3/N for CX layers. On Quantinuum H2-2, a four-qubit model ethylene demonstration with explicit inverse QFT and repeated phase-kickback steps up to 6 phase bits yields distinct energies and shows the auxiliary registers provide useful error detection filters.

Cite

@article{arxiv.2604.14921,
  title  = {Split-Evolution Quantum Phase Estimation for Particle-Conserving Hamiltonians},
  author = {Megan Cerys Rowe and Carlo A. Gaggioli and Ludmila Szulakowska and David Muñoz Ramo and David Zsolt Manrique},
  journal= {arXiv preprint arXiv:2604.14921},
  year   = {2026}
}
R2 v1 2026-07-01T12:12:31.199Z