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Resource-efficient Quantum Algorithms for Selected Hamiltonian Subspace Diagonalization

Quantum Physics 2026-03-16 v1 Chemical Physics

Abstract

Quantum algorithms for selecting a subspace of Hamiltonians to diagonalize have emerged as a promising alternative to variational algorithms in the NISQ era. So far, such algorithms, which include the quantum selected configuration interaction (QSCI) and sample-based quantum diagonalization (SQD), have been formulated in second-quantization in Fock space, which leads to inefficient usage of qubit resources. We introduce the first QSCI algorithm developed in the CI-matrix (CIM) framework, which is known to have optimal qubit scaling of exactly log2(NCSF)\lceil \log_2 (N_{CSF}) \rceil where NN is the size of the CIM. In addition, we introduce a novel single-bit flip error mitigation which comes at the overhead of a single qubit and we combine this with a stochastic approximate Trotterization evolution adapted from qDRIFT. Simulating benchmark N2_2 and naphthalene molecules on quantum hardware, our results achieved similar accuracy as SQD methods but with significantly less quantum resources. However, our CIM-QSCI algorithm and SQD methods could not match the performance of classical heat-bath CI (HCI) for the same task. Hence, we introduce an augmented version of QSCI called quantum selected heat-bath CI (QSHCI). This variant replaces classical heat-bath sampling with quantum sampling from QSCI to achieve performance comparable to HCI. We note that a current drawback of our approach is the preprocessing cost of O(N2logN)\mathcal{O}(N^2\log N) for constructing the CIM and performing the Pauli decomposition. This can be further improved by considering efficient CIM access models for the stochastic Trotter evolution.

Keywords

Cite

@article{arxiv.2603.13160,
  title  = {Resource-efficient Quantum Algorithms for Selected Hamiltonian Subspace Diagonalization},
  author = {Vincent Graves and Manqoba Q. Hlatshwayo and Theodoros Kapourniotis and Konstantinos Georgopoulos},
  journal= {arXiv preprint arXiv:2603.13160},
  year   = {2026}
}

Comments

18 pages, 5 figures

R2 v1 2026-07-01T11:18:45.170Z