Superconducting pairing correlations on a trapped-ion quantum computer
Abstract
The Fermi-Hubbard model is the starting point for the simulation of many strongly correlated materials, including high-temperature superconductors, whose modelling is a key motivation for the construction of quantum simulation and computing devices. However, the detection of superconducting pairing correlations has so far remained out of reach, both because of their off-diagonal character - which makes them inaccessible to local density measurements - and because of the difficulty of preparing superconducting states. Here, we report measurement of significant pairing correlations in three different regimes of Fermi-Hubbard models simulated on Quantinuum's Helios trapped-ion quantum computer. Specifically, we measure non-equilibrium pairing induced by an electromagnetic field in the half-filled square lattice model, d-wave pairing in an approximate ground state of the checkerboard Hubbard model at -doping, and s-wave pairing in a bilayer model relevant to nickelate superconductors. These results show that a quantum computer can reliably create and probe physically relevant states with superconducting pairing correlations, opening a path to the exploration of superconductivity with quantum computers.
Cite
@article{arxiv.2511.02125,
title = {Superconducting pairing correlations on a trapped-ion quantum computer},
author = {Etienne Granet and Sheng-Hsuan Lin and Kevin Hémery and Reza Haghshenas and Pablo Andres-Martinez and David T. Stephen and Anthony Ransford and Jake Arkinstall and M. S. Allman and Pete Campora and Samuel F. Cooper and Robert D. Delaney and Joan M. Dreiling and Brian Estey and Caroline Figgatt and Cameron Foltz and John P. Gaebler and Alex Hall and Ali Husain and Akhil Isanaka and Colin J. Kennedy and Nikhil Kotibhaskar and Ivaylo S. Madjarov and Michael Mills and Alistair R. Milne and Annie J. Park and Adam P. Reed and Brian Neyenhuis and Justin G. Bohnet and Michael Foss-Feig and Andrew C. Potter and Ramil Nigmatullin and Mohsin Iqbal and Henrik Dreyer},
journal= {arXiv preprint arXiv:2511.02125},
year = {2026}
}
Comments
7+63 pages, 3+29 figures. v2: added an author, updated author contributions, competing interest, acknowledgement, updated references, fixed typos and added some diagrams to Supplementary Section S4, updated Supplementary Figure S27b, v3: corrected typo in author name