English

BIonic membranes and AdS instabilities

High Energy Physics - Theory 2022-08-10 v4

Abstract

We study 4d membranes in type IIA flux compactifications of the form AdS4×X6_4 \times X_6, where X6X_6 admits a Calabi--Yau metric. These models feature scale separation and D6-branes/O6-planes on three-cycles of X6X_6. When the latter are treated as localised sources, explicit solutions to the 10d equations of motion and Bianchi identities are known in 4d N=1\mathcal{N}=1 settings, valid at first order in an expansion parameter related to the AdS4_4 cosmological constant. We extend such solutions to a family of perturbatively stable N=0\mathcal{N}=0 vacua, and analyse their non-perturbative stability by looking at 4d membranes. Up to the accuracy of the solution, we find that either D4-branes or anti-D4-branes on holomorphic curves feel no force in both N=1\mathcal{N} =1 and N=0\mathcal{N}=0 AdS4_4. Differently, D8-branes wrapping X6X_6 and with D6-branes ending on them can be superextremal 4d membranes attracted towards the N=0\mathcal{N}=0 AdS4_4 boundary. The sources of imbalance are the curvature of X6X_6 and the D8/D6 BIon profile, with both comparable terms as can be checked for X6X_6 a (blown-up) toroidal orbifold. We then show that simple N=0\mathcal{N}=0 vacua with space-time filling D6-branes are unstable against bubble nucleation, decaying to N=0\mathcal{N}=0 vacua with less D6-branes and larger Romans mass.

Keywords

Cite

@article{arxiv.2110.11370,
  title  = {BIonic membranes and AdS instabilities},
  author = {Fernando Marchesano and David Prieto and Joan Quirant},
  journal= {arXiv preprint arXiv:2110.11370},
  year   = {2022}
}

Comments

v4: Minor corrections, references added; v1:30 pages + appendices, 2 figures

R2 v1 2026-06-24T07:05:09.376Z