Quantum chemistry as a benchmark for near-term quantum computers

Alexander J. McCaskey, Zachary P. Parks, Jacek Jakowski, Shirley V. Moore, Titus D. Morris, Travis S. Humble, Raphael C. Pooser

Research output: Contribution to journalArticlepeer-review

142 Scopus citations

Abstract

We present a quantum chemistry benchmark for noisy intermediate-scale quantum computers that leverages the variational quantum eigensolver, active-space reduction, a reduced unitary coupled cluster ansatz, and reduced density purification as error mitigation. We demonstrate this benchmark using 4 of the available qubits on the 20-qubit IBM Tokyo and 16-qubit Rigetti Aspen processors via the simulation of alkali metal hydrides (NaH, KH, RbH), with accuracy of the computed ground state energy serving as the primary benchmark metric. We further parameterize this benchmark suite on the trial circuit type, the level of symmetry reduction, and error mitigation strategies. Our results demonstrate the characteristically high noise level present in near-term superconducting hardware, but provide a relevant baseline for future improvement of the underlying hardware, and a means for comparison across near-term hardware types. We also demonstrate how to reduce the noise in post processing with specific error mitigation techniques. Particularly, the adaptation of McWeeny purification of noisy density matrices dramatically improves accuracy of quantum computations, which, along with adjustable active space, significantly extends the range of accessible molecular systems. We demonstrate that for specific benchmark settings and a selected range of problems, the accuracy metric can reach chemical accuracy when computing over the cloud on certain quantum computers.

Original languageEnglish
Article number99
Journalnpj Quantum Information
Volume5
Issue number1
DOIs
StatePublished - Dec 1 2019

Funding

This manuscript has been authored by UT-Battelle, LLC under Contract No. DE-AC05-00OR22725 with the U.S. Department of Energy. The authors acknowledge fruitful discussions with E. Dumitrescu. R.C.P. acknowledges helpful discussions with R.S. Bennink. The authors acknowledge DOE ASCR funding under the Quantum Computing Testbed Pathfinder program, FWP number ERKJ332. Z.P. was supported in part by an appointment to the Oak Ridge National Laboratory HERE Program, sponsored by the U.S. Department of Energy and administered by the Oak Ridge Institute for Science and Education. This research used quantum computing system resources supported by the U.S. Department of Energy, Office of Science, Office of Advanced Scientific Computing Research program office.

FundersFunder number
DOE ASCR
FWPERKJ332
LLC
UT-Battelle
U.S. Department of Energy
Office of Science
Advanced Scientific Computing Research
Oak Ridge National Laboratory
Oak Ridge Institute for Science and Education

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