Digital quantum magnetism on a trapped-ion quantum computer
Abstract
Digital quantum matter -- realized when discrete quantum gates approximate continuous time evolution -- is susceptible to heating into chaotic, structureless states. If digitization errors are adequately suppressed, a long-lived transient regime of approximately energy-conserving dynamics can be observed on gate-based quantum computers. Conservation of energy, in turn, enables the exploration of a wide variety of complex behaviors observed in equilibrium systems, ranging from the nontrivial microscopic origins of thermalization itself to the stabilization of effective models hosting exotic emergent properties. Here, we use Quantinuum's system model H2 quantum computer to simulate digitized dynamics of the quantum Ising model, suppressing digitization errors well enough to observe thermalization on timescales that severely challenge classical simulation methods. Relaxation of an inhomogeneous state reveals an emergent hydrodynamics due to approximate energy conservation, and we compute the associated diffusion constant. By reprogramming our simulations to take place on a triangular lattice with periodic boundary conditions, we observe thermalization consistent with emergent gauge and topological constraints resulting from lattice frustration. Our results were enabled by continued advances in two-qubit gate quality (native partial entangler fidelities of ), and establish digital quantum computers as powerful tools for studying (effectively) continuous-time dynamics.
Cite
@article{arxiv.2503.20870,
title = {Digital quantum magnetism on a trapped-ion quantum computer},
author = {Reza Haghshenas and Eli Chertkov and Michael Mills and Wilhelm Kadow and Sheng-Hsuan Lin and Yi-Hsiang Chen and Chris Cade and Ido Niesen and Tomislav Begušić and Manuel S. Rudolph and Cristina Cirstoiu and Kevin Hemery and Conor Mc Keever and Michael Lubasch and Etienne Granet and Charles H. Baldwin and John P. Bartolotta and Matthew Bohn and Justin J. Burau and Julia Cline and Matthew DeCross and Joan M. Dreiling and Cameron Foltz and David Francois and John P. Gaebler and Christopher N. Gilbreth and Johnnie Gray and Dan Gresh and Alex Hall and Aaron Hankin and Azure Hansen and Nathan Hewitt and Craig A. Holliman and Ross B. Hutson and Mohsin Iqbal and Nikhil Kotibhaskar and Elliot Lehman and Dominic Lucchetti and Ivaylo S. Madjarov and Karl Mayer and Alistair R. Milne and Steven A. Moses and Brian Neyenhuis and Gunhee Park and Abigail R. Perry and Boris Ponsioen and Michael Schecter and Peter E. Siegfried and David T. Stephen and Bruce G. Tiemann and Maxwell D. Urmey and James Walker and Andrew C. Potter and David Hayes and Garnet Kin-Lic Chan and Frank Pollmann and Michael Knap and Henrik Dreyer and Michael Foss-Feig},
journal= {arXiv preprint arXiv:2503.20870},
year = {2026}
}
Comments
7 pages + Supplemental material