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Quantum computation of dominant products in lithium–sulfur batteries

Julia E. Rice, Tanvi P. Gujarati, Mario Motta, Tyler Y. Takeshita, Eunseok Lee, Joseph A. Latone, Jeannette M. Garcia

2021The Journal of Chemical Physics68 citationsDOIOpen Access PDF

Abstract

Quantum chemistry simulations of some industrially relevant molecules are reported, employing variational quantum algorithms for near-term quantum devices. The energies and dipole moments are calculated along the dissociation curves for lithium hydride (LiH), hydrogen sulfide, lithium hydrogen sulfide, and lithium sulfide. In all cases, we focus on the breaking of a single bond to obtain information about the stability of the molecular species being investigated. We calculate energies and a variety of electrostatic properties of these molecules using classical simulators of quantum devices, with up to 21 qubits for lithium sulfide. Moreover, we calculate the ground-state energy and dipole moment along the dissociation pathway of LiH using IBM quantum devices. This is the first example, to the best of our knowledge, of dipole moment calculations being performed on quantum hardware.

Topics & Concepts

Lithium hydrideDipoleQuantum computerQubitQuantumPhysicsChemistryQuantum mechanicsDissociation (chemistry)Atomic physicsMoleculeQuantum simulatorQuantum chemistryQuantum dynamicsBond-dissociation energyTransition dipole momentQuantum algorithmBond dipole momentLithium (medication)Computational chemistryHydrogenElectronic structureMolecular physicsQuantum informationChemical physicsQuantum numberAdvanced Battery Materials and TechnologiesQuantum optics and atomic interactionsPhotorefractive and Nonlinear Optics
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