Related papers: Onset of thermalization of q-deformed SU(2) Yang-Mills theory on a trapped-ion quantum computer

Onset of thermalization of q-deformed SU(2) Yang-Mills theory on a trapped-ion quantum computer

URL: http://arxiv.org/abs/2601.13530v1
Date: Tue, 20 Jan 2026 02:25:53 GMT
Title: Onset of thermalization of q-deformed SU(2) Yang-Mills theory on a trapped-ion quantum computer
Authors: Tomoya Hayata, Yoshimasa Hidaka, Yuta Kikuchi,
Abstract summary: We develop a quantum simulation of thermalization dynamics in a (2+1)-dimensional $q$-deformed $mathrmSU(2)_3$ Yang-Mills theory.<n>We successfully simulate the real-time dynamics of this model using quantum circuits that explicitly implement $F$-moves.
Score: 1.2744523252873352
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Nonequilibrium dynamics of quantum many-body systems is one of the main targets of quantum simulations. This focus - together with rapid advances in quantum-computing hardware - has driven increasing applications in high-energy physics, particularly in lattice gauge theories. However, most existing experimental demonstrations remain restricted to (1+1)-dimensional and/or abelian gauge theories, such as the Schwinger model and the toric code. It is essential to develop quantum simulations of nonabelian gauge theories in higher dimensions, addressing realistic problems in high-energy physics. To fill the gap, we demonstrate a quantum simulation of thermalization dynamics in a (2+1)-dimensional $q$-deformed $\mathrm{SU}(2)_3$ Yang-Mills theory using a trapped-ion quantum computer. By restricting the irreducible representations of the gauge fields to the integer-spin sector of $\mathrm{SU}(2)_3$, we obtain a simplified yet nontrivial model described by Fibonacci anyons, which preserves the essential nonabelian fusion structure of the gauge fields. We successfully simulate the real-time dynamics of this model using quantum circuits that explicitly implement $F$-moves. In our demonstrations, the quantum circuits execute up to 47 sequential $F$-moves. We identify idling errors as the dominant error source, which can be effectively mitigated using dynamical decoupling combined with a parallelized implementation of $F$-moves.

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