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Main Authors: Ngwenya, B. A., Rothkopf, A. K., Horowitz, W. A.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.21333
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author Ngwenya, B. A.
Rothkopf, A. K.
Horowitz, W. A.
author_facet Ngwenya, B. A.
Rothkopf, A. K.
Horowitz, W. A.
contents We present non-perturbative results of the Casimir potential in non-abelian SU(3) gauge theory in (2+1)D and (3+1)D in the confined and deconfined phase. For the first time, geometries beyond parallel plates in (3+1)D are explored and we show that the Casimir effect for the symmetrical tube and symmetrical box is attractive. The Casimir potential for the tube differs from the massless non-interacting scalar field theory prediction, where a repulsive Casimir potential is expected. Unlike the parallel plate geometry where the plate-size is fixed, in the case of the tube and box, the sizes of the faces forming the walls of the geometries changes with separation distance. We propose various methods that can be used to account for the energy contributions from creating the boundaries. We show that increasing the temperature from a confined to a deconfined phase does not alter the Casimir potential. This observation is consistent with prior work suggesting that the region inside the walls is a boundary induced deconfined phase.
format Preprint
id arxiv_https___arxiv_org_abs_2507_21333
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The Non-Abelian Casimir Effect for Plates, Symmetrical Tube and Box on the Lattice
Ngwenya, B. A.
Rothkopf, A. K.
Horowitz, W. A.
High Energy Physics - Lattice
High Energy Physics - Phenomenology
Quantum Physics
We present non-perturbative results of the Casimir potential in non-abelian SU(3) gauge theory in (2+1)D and (3+1)D in the confined and deconfined phase. For the first time, geometries beyond parallel plates in (3+1)D are explored and we show that the Casimir effect for the symmetrical tube and symmetrical box is attractive. The Casimir potential for the tube differs from the massless non-interacting scalar field theory prediction, where a repulsive Casimir potential is expected. Unlike the parallel plate geometry where the plate-size is fixed, in the case of the tube and box, the sizes of the faces forming the walls of the geometries changes with separation distance. We propose various methods that can be used to account for the energy contributions from creating the boundaries. We show that increasing the temperature from a confined to a deconfined phase does not alter the Casimir potential. This observation is consistent with prior work suggesting that the region inside the walls is a boundary induced deconfined phase.
title The Non-Abelian Casimir Effect for Plates, Symmetrical Tube and Box on the Lattice
topic High Energy Physics - Lattice
High Energy Physics - Phenomenology
Quantum Physics
url https://arxiv.org/abs/2507.21333