English

Simulating dirty bosons on a quantum computer

Disordered Systems and Neural Networks 2022-10-18 v1 Quantum Gases Strongly Correlated Electrons Quantum Physics

Abstract

The physics of dirty bosons highlights the intriguing interplay of disorder and interactions in quantum systems, playing a central role in describing, for instance, ultracold gases in a random potential, doped quantum magnets, and amorphous superconductors. Here, we demonstrate how quantum computers can be used to elucidate the physics of dirty bosons in one and two dimensions. Specifically, we explore the disorder-induced delocalized-to-localized transition using adiabatic state preparation. In one dimension, the quantum circuits can be compressed to small enough depths for execution on currently available quantum computers. In two dimensions, the compression scheme is no longer applicable, thereby requiring the use of large-scale classical state vector simulations to emulate quantum computer performance. In addition, simulating interacting bosons via emulation of a noisy quantum computer allowed us to study the effect of quantum hardware noise on the physical properties of the simulated system. Our results suggest that scaling laws control how noise modifies observables versus its strength, the circuit depth, and the number of qubits. Moreover, we observe that noise impacts the delocalized and localized phases differently. A better understanding of how noise alters the genuine properties of the simulated system is essential for leveraging noisy intermediate-scale quantum devices for simulation of dirty bosons, and indeed for condensed matter systems in general.

Keywords

Cite

@article{arxiv.2210.08386,
  title  = {Simulating dirty bosons on a quantum computer},
  author = {Lindsay Bassman Oftelie and Roel Van Beeumen and Daan Camps and Wibe A. de Jong and Maxime Dupont},
  journal= {arXiv preprint arXiv:2210.08386},
  year   = {2022}
}

Comments

15 pages, 7 figures

R2 v1 2026-06-28T03:43:41.446Z