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How a Quantum Computer Could Quantify Uncertainty in Microkinetic Models

Alejandro Becerra, A. Prabhu, Mary Sharmila Rongali, Sri Charan Simha Velpur, Bert Debusschere, Eric A. Walker

2021The Journal of Physical Chemistry Letters13 citationsDOIOpen Access PDF

Abstract

A method of uncertainty quantification on a quantum circuit using three samples for the Rh(111)-catalyzed CO oxidation reaction is demonstrated. Three parametrized samples of a reduced, linearized microkinetic model populate a single block diagonal matrix for a quantum circuit. This approach leverages the logarithmic scaling of the number of qubits with respect to matrix size. The Harrow, Hassidim, and Lloyd (HHL) algorithm for solving linear systems is employed, and the results are compared with the classical results. This application area of uncertainty quantification in chemical kinetics can experience a quantum advantage using the method reported here, although issues related to larger systems are discussed.

Topics & Concepts

ScalingQuantumLogarithmDiagonalComputer scienceLinear scaleMatrix (chemical analysis)QubitQuantum computerQuantum chemicalStatistical physicsAlgorithmMathematical optimizationMathematicsChemistryQuantum mechanicsPhysicsMoleculeGeodesyGeographyChromatographyGeometryMathematical analysisQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum and electron transport phenomena
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