Abstract
Quantum chemistry is a key application area for noisy-intermediate scale quantum (NISQ) devices, and therefore serves as an important benchmark for current and future quantum computer performance. Previous benchmarks in this field have focused on variational methods for computing ground and excited states of various molecules, including a benchmarking suite focused on the performance of computing ground states for alkali-hydrides under an array of error mitigation methods. State-of-the-art methods to reach chemical accuracy in hybrid quantum-classical electronic structure calculations of alkali hydride molecules on NISQ devices from IBM are outlined here. It is demonstrated how to extend the reach of variational eigensolvers with symmetry preserving Ansätze. Next, it is outlined how to use quantum imaginary time evolution and Lanczos as a complementary method to variational techniques, highlighting the advantages of each approach. Finally, a new error mitigation method is demonstrated which uses systematic error cancellation via hidden inverse gate constructions, improving the performance of typical variational algorithms. These results show that electronic structure calculations have advanced rapidly, to routine chemical accuracy for simple molecules, from their inception on quantum computers a few short years ago, and they point to further rapid progress to larger molecules as the power of NISQ devices grows.
Original language | English |
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Article number | 2100012 |
Journal | Advanced Quantum Technologies |
Volume | 4 |
Issue number | 7 |
DOIs | |
State | Published - Jul 2021 |
Funding
The quantum circuits were drawn using Q‐circuit package. This work was supported by the ASCR Quantum Testbed Pathfinder program at Oak Ridge National Laboratory under FWP number ERKJ332. This research used quantum computing system resources of the Oak Ridge Leadership Computing Facility, which is a DOE Office of Science User Facility supported under Contract DE‐AC05‐00OR22725. S.M. was supported through US Department of Energy grant DE‐SC0019294 awarded to Duke and is funded in part by an NSF QISE‐NET fellowship (DMR‐1747426). G.B. and B.G. were supported through US Department of Energy grants awarded to Virginia Tech (Awards DE‐SC0019318 and DE‐SC0019199, respectively). G.S. acknowledges the Army Research Office award W911NF‐19‐1‐0397 and the National Science Foundation award OMA‐1937008. [ 50 ] The quantum circuits were drawn using Q-circuit package.[50] This work was supported by the ASCR Quantum Testbed Pathfinder program at Oak Ridge National Laboratory under FWP number ERKJ332. This research used quantum computing system resources of the Oak Ridge Leadership Computing Facility, which is a DOE Office of Science User Facility supported under Contract DE-AC05-00OR22725. S.M. was supported through US Department of Energy grant DE-SC0019294 awarded to Duke and is funded in part by an NSF QISE-NET fellowship (DMR-1747426). G.B. and B.G. were supported through US Department of Energy grants awarded to Virginia Tech (Awards DE-SC0019318 and DE-SC0019199, respectively). G.S. acknowledges the Army Research Office award W911NF-19-1-0397 and the National Science Foundation award?OMA-1937008.
Funders | Funder number |
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FWP | ERKJ332 |
National Science Foundation | DE‐SC0019199, OMA‐1937008, DE-SC0019318, DMR‐1747426, -1937008 |
U.S. Department of Energy | DE‐SC0019294 |
Directorate for Mathematical and Physical Sciences | 1747426 |
Army Research Office | W911NF‐19‐1‐0397 |
Office of Science | DE‐AC05‐00OR22725 |
Advanced Scientific Computing Research | |
Oak Ridge National Laboratory |
Keywords
- quantum benchmarks
- quantum chemistry
- quantum computing
- quantum imaginary time evolution
- variational algorithms