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Reducing Qubit Requirements while Maintaining Numerical Precision for the Variational Quantum Eigensolver: A Basis-Set-Free Approach

Jakob S. Kottmann, Philipp Schleich, Teresa Tamayo-Mendoza, Alán Aspuru‐Guzik

2021The Journal of Physical Chemistry Letters52 citationsDOIOpen Access PDF

Abstract

We present a basis-set-free approach to the variational quantum eigensolver using an adaptive representation of the spatial part of molecular wave functions. Our approach directly determines system-specific representations of qubit Hamiltonians while fully omitting globally defined basis sets. In this work, we use directly determined pair-natural orbitals on the level of second-order perturbation theory. This results in compact qubit Hamiltonians with high numerical accuracy. We demonstrate initial applications with compact Hamiltonians on up to 22 qubits where conventional representation would for the same systems require 40-100 or more qubits. We further demonstrate reductions in the quantum circuits through the structure of the pair-natural orbitals.

Topics & Concepts

QubitBasis (linear algebra)Representation (politics)QuantumFlux qubitAtomic orbitalQuantum computerBasis setQuantum algorithmPerturbation theory (quantum mechanics)Perturbation (astronomy)Quantum mechanicsComputer scienceTopology (electrical circuits)MathematicsPhysicsGeometryDensity functional theoryPoliticsCombinatoricsPolitical scienceElectronLawQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum and electron transport phenomena