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Ground-state energy estimation of the water molecule on a trapped ion quantum computer

Y. Nam, Jwo-Sy Chen, N. Pisenti, K. Wright, Conor Delaney, D. Maslov, K. Brown, Stewart Allen, J. Amini, Joel Apisdorf, K. Beck, Aleksey Blinov, Vandiver Chaplin, Mika Chmielewski, Coleman Collins, S. Debnath, Andrew M. Ducore, K. Hudek, Matthew J. Keesan, Sarah M. Kreikemeier, J. Mizrahi, Phil Solomon, Mike Williams, J. D. Wong-Campos, C. Monroe, Jungsang Kim·February 26, 2019
PhysicsComputer ScienceMathematics

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Abstract

Quantum computing leverages the quantum resources of superposition and entanglement to efficiently solve computational problems considered intractable for classical computers. Examples include calculating molecular and nuclear structure, simulating strongly-interacting electron systems, and modeling aspects of material function. While substantial theoretical advances have been made in mapping these problems to quantum algorithms, there remains a large gap between the resource requirements for solving such problems and the capabilities of currently available quantum hardware. Bridging this gap will require a co-design approach, where the expression of algorithms is developed in conjunction with the hardware itself to optimize execution. Here, we describe a scalable co-design framework for solving chemistry problems on a trapped ion quantum computer, and apply it to compute the ground-state energy of the water molecule. The robust operation of the trapped ion quantum computer yields energy estimates with errors approaching the chemical accuracy, which is the target threshold necessary for predicting the rates of chemical reaction dynamics.

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