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Reducing Qubit Requirements for Quantum Simulations Using Molecular Point Group Symmetries

Kanav Setia, Richard Chen, Julia E. Rice, Antonio Mezzacapo, Marco Pistoia, James Whitfield

2020Journal of Chemical Theory and Computation120 citationsDOIOpen Access PDF

Abstract

Simulating molecules is believed to be one of the early stage applications for quantum computers. Current state-of-the-art quantum computers are limited in size and coherence; therefore, optimizing resources to execute quantum algorithms is crucial. In this work, we develop the second quantization representation of spatial symmetries, which are then transformed to their qubit operator representation. These qubit operator representations are used to reduce the number of qubits required for simulating molecules. We present our results for various molecules and elucidate a formal connection of this work with a previous technique that analyzed generic Z2 Pauli symmetries.

Topics & Concepts

QubitCoherence (philosophical gambling strategy)Computer scienceOperator (biology)QuantumHomogeneous spacePauli exclusion principleRepresentation (politics)Quantization (signal processing)Quantum computerPauli matricesTheoretical computer scienceQuantum mechanicsPhysicsTheoretical physicsAlgorithmMathematicsChemistryPolitical scienceGeometryRepressorTranscription factorGeneLawPoliticsBiochemistryQuantum Computing Algorithms and ArchitectureProtein Structure and DynamicsFractal and DNA sequence analysis
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