Wilson loops and spherical branes

Davide Astesiano; Pieter Bomans; Fridrik Freyr Gautason; Valentina Giangreco M. Puletti; Alexia Nix

doi:10.21468/SciPostPhys.18.2.050

Wilson loops and spherical branes

Davide Astesiano^*, Pieter Bomans, Fridrik Freyr Gautason, Valentina Giangreco M. Puletti, Alexia Nix

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

We study 1/2 -BPS Wilson loop operators in maximally supersymmetric Yang-Mills theory on d-dimensional spheres. Their vacuum expectation values can be computed at large N through supersymmetric localisation. The holographic duals are given by back-reacted spherical D-branes. For d ≠ 4, the resulting theories are non-conformal and correspondingly, the dual geometries do not possess an asymptotic AdS region. The main aim of this work is to compute the holographic Wilson loops by evaluating the partition function of a probe fundamental string and M2-brane in the dual geometry, focusing on the next-to-leading order. Along the way, we highlight a variety of issues related to the presence of a non-constant dilaton. In particular, the structure of the divergences of the one-loop partition functions takes a non-universal form in contrast to examples available in the literature. We devise a general framework to treat the divergences, successfully match the sub-leading scaling with λ and N, and provide a first step towards obtaining the numerical prefactor.

Original language	English
Article number	050
Journal	SciPost Physics
Volume	18
Issue number	2
DOIs	https://doi.org/10.21468/SciPostPhys.18.2.050
Publication status	Published - Feb 2025

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Copyright D. Astesiano et al.

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abstract = "We study 1/2 -BPS Wilson loop operators in maximally supersymmetric Yang-Mills theory on d-dimensional spheres. Their vacuum expectation values can be computed at large N through supersymmetric localisation. The holographic duals are given by back-reacted spherical D-branes. For d ≠ 4, the resulting theories are non-conformal and correspondingly, the dual geometries do not possess an asymptotic AdS region. The main aim of this work is to compute the holographic Wilson loops by evaluating the partition function of a probe fundamental string and M2-brane in the dual geometry, focusing on the next-to-leading order. Along the way, we highlight a variety of issues related to the presence of a non-constant dilaton. In particular, the structure of the divergences of the one-loop partition functions takes a non-universal form in contrast to examples available in the literature. We devise a general framework to treat the divergences, successfully match the sub-leading scaling with λ and N, and provide a first step towards obtaining the numerical prefactor.",

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AU - Bomans, Pieter

AU - Gautason, Fridrik Freyr

AU - Puletti, Valentina Giangreco M.

AU - Nix, Alexia

N1 - Publisher Copyright: Copyright D. Astesiano et al.

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Y1 - 2025/2

N2 - We study 1/2 -BPS Wilson loop operators in maximally supersymmetric Yang-Mills theory on d-dimensional spheres. Their vacuum expectation values can be computed at large N through supersymmetric localisation. The holographic duals are given by back-reacted spherical D-branes. For d ≠ 4, the resulting theories are non-conformal and correspondingly, the dual geometries do not possess an asymptotic AdS region. The main aim of this work is to compute the holographic Wilson loops by evaluating the partition function of a probe fundamental string and M2-brane in the dual geometry, focusing on the next-to-leading order. Along the way, we highlight a variety of issues related to the presence of a non-constant dilaton. In particular, the structure of the divergences of the one-loop partition functions takes a non-universal form in contrast to examples available in the literature. We devise a general framework to treat the divergences, successfully match the sub-leading scaling with λ and N, and provide a first step towards obtaining the numerical prefactor.

AB - We study 1/2 -BPS Wilson loop operators in maximally supersymmetric Yang-Mills theory on d-dimensional spheres. Their vacuum expectation values can be computed at large N through supersymmetric localisation. The holographic duals are given by back-reacted spherical D-branes. For d ≠ 4, the resulting theories are non-conformal and correspondingly, the dual geometries do not possess an asymptotic AdS region. The main aim of this work is to compute the holographic Wilson loops by evaluating the partition function of a probe fundamental string and M2-brane in the dual geometry, focusing on the next-to-leading order. Along the way, we highlight a variety of issues related to the presence of a non-constant dilaton. In particular, the structure of the divergences of the one-loop partition functions takes a non-universal form in contrast to examples available in the literature. We devise a general framework to treat the divergences, successfully match the sub-leading scaling with λ and N, and provide a first step towards obtaining the numerical prefactor.

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Wilson loops and spherical branes

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