Quantum Solvers for Nonlinear Matrix Equations in Quantum Chemistry
摘要
We present a quantum algorithm for solving algebraic Riccati equations, with applications to quantum-chemical random-phase approximation (RPA) and higher-order RPA theories. Our method block-encodes stabilizing Riccati solutions via Riesz projectors onto invariant subspaces of an associated non-normal matrix, implemented using contour-integral resolvents and quantum singular value transformations. Applied to -particle, -hole RPA, our algorithm yields a block-encoding of the amplitude solution and estimates the electronic correlation-energy density with it. Under localized-orbital sparsity assumptions, the end-to-end cost scales linearly with system size and polynomially with excitation rank , suggesting an exponential advantage in over plausible classical local-correlation heuristics. More broadly, this work provides a framework for quantum algorithms for nonlinear matrix equations in quantum chemistry and opens a possible route toward developing quantum algorithms for coupled-cluster theory.
引用
@article{arxiv.2605.16189,
title = {Quantum Solvers for Nonlinear Matrix Equations in Quantum Chemistry},
author = {Pablo Rodenas-Ruiz and Andrew Zhao and Joonho Lee},
journal= {arXiv preprint arXiv:2605.16189},
year = {2026}
}
备注
8+30 pages, 1+4 figures