Variational quantum eigensolvers fail before optimization begins when strong correlation splits the molecular energy landscape into competing basins and the initial state selects a non-ground-state basin. We introduce a geometry-conditioned preconditioner Peq:R↦θ0 constrained by the SE(3) covariance of the molecular Hamiltonian, so that nuclear geometry is mapped directly into circuit parameters in the correlated ground-state basin. This basin localization changes the relevant gradient statistics from concentration controlled to curvature controlled. In statevector benchmarks on six stretched molecules, Peq reduces Hartree--Fock initialization errors by factors of 38×--6250×, reaches sub-mHa initialization in CO, LiH, and H8, and places N2, H2O, and BeH2 in the mHa-scale correlated basin. In disordered H10 chains, equivariant basin targeting and stochastic escape reach unit success probability at fixed optimization budget. The procedure performs basin selection before the shot-limited quantum loop; the quantum circuit then refines correlation inside the selected basin.
Cite
@article{arxiv.2605.09909,
title = {Symmetry-Protected Basin Localization in Variational Quantum Eigensolvers},
author = {Yangshuai Wang},
journal= {arXiv preprint arXiv:2605.09909},
year = {2026}
}