Shortcut to Chemically Accurate Quantum Computing via Density-based Basis-set Correction
Abstract
Using GPU-accelerated state-vector emulation, we propose to embed a quantum computing ansatz into density-functional theory via density-based basis-set corrections (DBBSC) to obtain quantitative quantum-chemistry results on molecules that would otherwise require brute-force quantum calculations using hundreds of logical qubits. Indeed, accessing a quantitative description of chemical systems while minimizing quantum resources is an essential challenge given the limited qubit capabilities of current quantum processors. We provide a shortcut towards chemically accurate quantum computations by approaching the complete-basis-set limit through coupling the DBBSC approach, applied to any given variational ansatz, to an on-the-fly crafting of basis sets specifically adapted to a given system and user-defined qubit budget. The resulting approach self-consistently accelerates the basis-set convergence, improving electronic densities, ground-state energies, and first-order properties (e.g. dipole moments), but can also serve as a classical, a posteriori, energy correction to quantum hardware calculations with expected applications in drug design and materials science.
Cite
@article{arxiv.2405.11567,
title = {Shortcut to Chemically Accurate Quantum Computing via Density-based Basis-set Correction},
author = {Diata Traore and Olivier Adjoua and César Feniou and Ioanna-Maria Lygatsika and Yvon Maday and Evgeny Posenitskiy and Kerstin Hammernik and Alberto Peruzzo and Julien Toulouse and Emmanuel Giner and Jean-Philip Piquemal},
journal= {arXiv preprint arXiv:2405.11567},
year = {2024}
}