Universidad Complutense de Madrid
E-Prints Complutense

Advantages of unfair quantum ground-state sampling

Impacto

Downloads

Downloads per month over past year

Zhang, Brian Hu and Wagenbreth, Gene and Martín Mayor, Víctor and Hens, Itay (2017) Advantages of unfair quantum ground-state sampling. Scientific reports, 95 (4). ISSN 2045-2322

[thumbnail of MartínMayorV Libre 46+CC.pdf]
Preview
PDF
Creative Commons Attribution.

2MB

Official URL: http://dx.doi.org/10.1038/s41598-017-01096-6




Abstract

The debate around the potential superiority of quantum annealers over their classical counterparts has been ongoing since the inception of the field. Recent technological breakthroughs, which have led to the manufacture of experimental prototypes of quantum annealing optimizers with sizes approaching the practical regime, have reignited this discussion. However, the demonstration of quantum annealing speedups remains to this day an elusive albeit coveted goal. We examine the power of quantum annealers to provide a different type of quantum enhancement of practical relevance, namely, their ability to serve as useful samplers from the ground-state manifolds of combinatorial optimization problems. We study, both numerically by simulating stoquastic and non-stoquastic quantum annealing processes, and experimentally, using a prototypical quantum annealing processor, the ability of quantum annealers to sample the ground-states of spin glasses differently than thermal samplers. We demonstrate that (i) quantum annealers sample the ground-state manifolds of spin glasses very differently than thermal optimizers (ii) the nature of the quantum fluctuations driving the annealing process has a decisive effect on the final distribution, and (iii) the experimental quantum annealer samples ground-state manifolds significantly differently than thermal and ideal quantum annealers. We illustrate how quantum annealers may serve as powerful tools when complementing standard sampling algorithms.


Item Type:Article
Additional Information:

© 2017 Macmillan Publishers Limited. This research used resources of the Oak Ridge Leadership Computing Facility at the Oak Ridge National Laboratory, which is supported by the Office of Science of the U.S. Department of Energy under Contract No. DEAC05-00OR22725. Computation for the work described here was also supported by the University of Southern California’s Center for High-Performance Computing (http://hpcc.usc.edu).

Uncontrolled Keywords:Ising spin-glass; Model
Subjects:Sciences > Physics > Physics-Mathematical models
ID Code:43063
Deposited On:11 Jul 2017 08:44
Last Modified:11 Jul 2017 08:44

Origin of downloads

Repository Staff Only: item control page