Litcius/Paper detail

Toward Quantum Computing for High-Energy Excited States in Molecular Systems: Quantum Phase Estimations of Core-Level States

Nicholas P. Bauman, Hongbin Liu, Eric J. Bylaska, Sriram Krishnamoorthy, Guang Hao Low, Christopher Granade, Nathan Wiebe, Nathan Baker, Bo Peng, Martin Roetteler, Matthias Troyer, Karol Kowalski

2020Journal of Chemical Theory and Computation39 citationsDOI

Abstract

This paper explores the utility of the quantum phase estimation (QPE) algorithm in calculating high-energy excited states characterized by the promotion of electrons occupying core-level shells. These states have been intensively studied over the last few decades, especially in supporting the experimental effort at light sources. Results obtained with QPE are compared with various high-accuracy many-body techniques developed to describe core-level states. The feasibility of the quantum phase estimator in identifying classes of challenging shake-up states characterized by the presence of higher-order excitation effects is discussed. We also demonstrate the utility of the QPE algorithm in targeting excitations from specific centers in a molecule. Lastly, we discuss how the lowest-order Trotter formula can be applied to reducing the complexity of the ansatz without affecting the error.

Topics & Concepts

Excited stateCore (optical fiber)QuantumAnsatzComputer scienceEstimatorPhase (matter)PhysicsStatistical physicsExcitationEnergy (signal processing)Quantum mechanicsMathematicsStatisticsTelecommunicationsAdvanced Chemical Physics StudiesSpectroscopy and Quantum Chemical StudiesSpectroscopy and Laser Applications
Toward Quantum Computing for High-Energy Excited States in Molecular Systems: Quantum Phase Estimations of Core-Level States | Litcius