English

Monodromy Defects from Hyperbolic Space

High Energy Physics - Theory 2022-02-23 v2 Strongly Correlated Electrons

Abstract

We study monodromy defects in O(N)O(N) symmetric scalar field theories in dd dimensions. After a Weyl transformation, a monodromy defect may be described by placing the theory on S1×Hd1S^1\times H^{d-1}, where Hd1H^{d-1} is the hyperbolic space, and imposing on the fundamental fields a twisted periodicity condition along S1S^1. In this description, the codimension two defect lies at the boundary of Hd1H^{d-1}. We first study the general monodromy defect in the free field theory, and then develop the large NN expansion of the defect in the interacting theory, focusing for simplicity on the case of NN complex fields with a one-parameter monodromy condition. We also use the ϵ\epsilon-expansion in d=4ϵd=4-\epsilon, providing a check on the large NN approach. When the defect has spherical geometry, its expectation value is a meaningful quantity, and it may be obtained by computing the free energy of the twisted theory on S1×Hd1S^1\times H^{d-1}. It was conjectured that the logarithm of the defect expectation value, suitably multiplied by a dimension dependent sine factor, should decrease under a defect RG flow. We check this conjecture in our examples, both in the free and interacting case, by considering a defect RG flow that corresponds to imposing alternate boundary conditions on one of the low-lying Kaluza-Klein modes on Hd1H^{d-1}. We also show that, adapting standard techniques from the AdS/CFT literature, the S1×Hd1S^1\times H^{d-1} setup is well suited to the calculation of the defect CFT data, and we discuss various examples, including one-point functions of bulk operators, scaling dimensions of defect operators, and four-point functions of operator insertions on the defect.

Keywords

Cite

@article{arxiv.2102.11815,
  title  = {Monodromy Defects from Hyperbolic Space},
  author = {Simone Giombi and Elizabeth Helfenberger and Ziming Ji and Himanshu Khanchandani},
  journal= {arXiv preprint arXiv:2102.11815},
  year   = {2022}
}

Comments

64 pages, 8 figures, v2: Typos corrected, references added, enhanced discussion in section 4

R2 v1 2026-06-23T23:26:45.587Z