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Main Authors: Cucchieri, Attilio, Mendes, Tereza
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.07730
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author Cucchieri, Attilio
Mendes, Tereza
author_facet Cucchieri, Attilio
Mendes, Tereza
contents We expand our previous study [1] of replicated gauge configurations in lattice SU(Nc) Yang-Mills theory -- employing Bloch's theorem, from condensed-matter physics -- to construct gauge-fixed field configurations on significantly larger lattices than the original, or primitive, one. We present a comprehensive discussion of the general gauge-fixing problem, identifying advantages of the replicated-lattice approach. In particular, the consideration of Bloch waves leads us to a visualization of the extended gauge-fixed configurations in terms of (color) magnetization domains. Moreover, we are able to explore features of the method to optimize the evaluation of gauge fields in momentum space, furthering our knowledge of the ``allowed momenta'', an issue that has hindered wider applications of this approach up to now. Interestingly, our analysis yields both a better conceptual understanding of the problem and a more efficient way to compute the desired large-volume observables.
format Preprint
id arxiv_https___arxiv_org_abs_2506_07730
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Bloch Waves, Magnetization and Domain Walls: The Case of the Gluon Propagator
Cucchieri, Attilio
Mendes, Tereza
High Energy Physics - Lattice
We expand our previous study [1] of replicated gauge configurations in lattice SU(Nc) Yang-Mills theory -- employing Bloch's theorem, from condensed-matter physics -- to construct gauge-fixed field configurations on significantly larger lattices than the original, or primitive, one. We present a comprehensive discussion of the general gauge-fixing problem, identifying advantages of the replicated-lattice approach. In particular, the consideration of Bloch waves leads us to a visualization of the extended gauge-fixed configurations in terms of (color) magnetization domains. Moreover, we are able to explore features of the method to optimize the evaluation of gauge fields in momentum space, furthering our knowledge of the ``allowed momenta'', an issue that has hindered wider applications of this approach up to now. Interestingly, our analysis yields both a better conceptual understanding of the problem and a more efficient way to compute the desired large-volume observables.
title Bloch Waves, Magnetization and Domain Walls: The Case of the Gluon Propagator
topic High Energy Physics - Lattice
url https://arxiv.org/abs/2506.07730