English

Quantum Algorithms for Geologic Fracture Networks

Quantum Physics 2023-02-21 v1 Computational Engineering, Finance, and Science Computational Physics

Abstract

Solving large systems of equations is a challenge for modeling natural phenomena, such as simulating subsurface flow. To avoid systems that are intractable on current computers, it is often necessary to neglect information at small scales, an approach known as coarse-graining. For many practical applications, such as flow in porous, homogenous materials, coarse-graining offers a sufficiently-accurate approximation of the solution. Unfortunately, fractured systems cannot be accurately coarse-grained, as critical network topology exists at the smallest scales, including topology that can push the network across a percolation threshold. Therefore, new techniques are necessary to accurately model important fracture systems. Quantum algorithms for solving linear systems offer a theoretically-exponential improvement over their classical counterparts, and in this work we introduce two quantum algorithms for fractured flow. The first algorithm, designed for future quantum computers which operate without error, has enormous potential, but we demonstrate that current hardware is too noisy for adequate performance. The second algorithm, designed to be noise resilient, already performs well for problems of small to medium size (order 10 to 1000 nodes), which we demonstrate experimentally and explain theoretically. We expect further improvements by leveraging quantum error mitigation and preconditioning.

Keywords

Cite

@article{arxiv.2210.11685,
  title  = {Quantum Algorithms for Geologic Fracture Networks},
  author = {Jessie M. Henderson and Marianna Podzorova and M. Cerezo and John K. Golden and Leonard Gleyzer and Hari S. Viswanathan and Daniel O'Malley},
  journal= {arXiv preprint arXiv:2210.11685},
  year   = {2023}
}

Comments

20 pages, 12 figures

R2 v1 2026-06-28T04:08:36.896Z