English

A quantum eigenvalue solver based on tensor networks

Quantum Physics 2026-02-06 v3

Abstract

Electronic ground states are of central importance in chemical simulations, but have remained beyond the reach of efficient classical algorithms except in cases of weak electron correlation or one-dimensional spatial geometry. We introduce a hybrid quantum-classical eigenvalue solver that constructs a wavefunction ansatz from a linear combination of matrix product states in rotated orbital bases, enabling the characterization of strongly correlated ground states with arbitrary spatial geometry. The energy is converged via a gradient-free generalized sweep algorithm based on quantum subspace diagonalization, with a potentially exponential speedup in the off-diagonal matrix element contractions upon translation into compact quantum circuits of linear depth in the number of qubits. Chemical accuracy is attained in numerical experiments for both a stretched water molecule and an octahedral arrangement of hydrogen atoms, achieving substantially better correlation energies compared to a unitary coupled-cluster benchmark, with orders of magnitude reductions in quantum resource estimates and a surprisingly high tolerance to shot noise. This proof-of-concept study suggests a promising new avenue for scaling up simulations of strongly correlated chemical systems on near-term quantum hardware.

Keywords

Cite

@article{arxiv.2404.10223,
  title  = {A quantum eigenvalue solver based on tensor networks},
  author = {Oskar Leimkuhler and K. Birgitta Whaley},
  journal= {arXiv preprint arXiv:2404.10223},
  year   = {2026}
}

Comments

29 pages, 15 figures

R2 v1 2026-06-28T15:55:18.221Z