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Quantum equation of motion for computing molecular excitation energies on a noisy quantum processor

Pauline J. Ollitrault, Abhinav Kandala, Chun-Fu Chen, Panagiotis Kl. Barkoutsos, Antonio Mezzacapo, Marco Pistoia, Sarah Sheldon, Stefan Woerner, Jay M. Gambetta, Ivano Tavernelli

2020Physical Review Research194 citationsDOIOpen Access PDF

Abstract

The computation of molecular excitation energies is essential for predicting photo-induced reactions of chemical and technological interest. While the classical computing resources needed for this task scale poorly, quantum algorithms emerge as promising alternatives. In particular, the extension of the variational quantum eigensolver algorithm to the computation of the excitation energies is an attractive option. However, there is currently a lack of such algorithms for correlated molecular systems that is amenable to near-term, noisy hardware. In this work, we propose an extension of the well-established classical equation of motion approach to a quantum algorithm for the calculation of molecular excitation energies on noisy quantum computers. In particular, we demonstrate the efficiency of this approach in the calculation of the excitation energies of the LiH molecule on an IBM Quantum computer.

Topics & Concepts

ExcitationQuantum computerQuantumComputationQuantum algorithmPhysicsIBMQuantum mechanicsEquations of motionStatistical physicsMotion (physics)Quantum systemExtension (predicate logic)Quantum dynamicsQuantum phase estimation algorithmQuantum numberAlgorithmScale (ratio)Task (project management)Computer scienceQuantum processClassical mechanicsComputational complexity theoryQuantum chemistryQuantum operationMoleculeOpen quantum systemSchrödinger equationQuantum Computing Algorithms and ArchitectureQuantum-Dot Cellular AutomataMachine Learning in Materials Science
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