Generalized Calibrations & the Characterization of M2-Brane Backgrounds

TL;DR

This paper develops a framework using generalized calibrations to classify supergravity backgrounds created by M2-branes wrapping cycles in Calabi-Yau manifolds, advancing understanding of flux-preserving supersymmetric geometries.

Contribution

It introduces a probe-based method to identify generalized calibrations, enabling complete classification of flux backgrounds with wrapped M2-branes.

Findings

Derived conditions for supersymmetry preservation in flux backgrounds.

Identified generalized calibrations through charged probe analysis.

Classified M2-brane backgrounds in Calabi-Yau geometries.

Abstract

As a step towards the classification of supergravity backgrounds with flux, we study the (back-reacted) geometry created by a BPS M2-brane when it wraps a cycle in a Calabi-Yau manifold. If it is to preserve supersymmetry, the membrane background must obey certain conditions. These conditions are expressed as geometrical constraints on differential forms and as such, can be interpreted as calibrations. Knowing the complete set of calibrations is the same as satisfying all conditions needed for supersymmetry preservation. While a purely geometric background is completely specified through standard calibrations, in order to fully describe a flux background, we must also state its generalized calibrations. These can be found by probing the background with BPS branes. The logic is simple. Since a BPS probe is guaranteed to be stable, we require that its volume be given by a calibrated form. This applies equally to both charged and uncharged probes; the former are stabilized by flux whereas the latter achieve stability by minimizing their volumes. Volume-forms of charged probes correspond to generalized calibrations and those of uncharged probes, to standard calibrations. Previously geometries were probed only by uncharged branes. The calibrations that were found had then to be supplemented by additional conditions in order to guarantee supersymmetry preservation in backgrounds with flux. Once the scope is broadened to include charged branes, the 'missing conditions' (generalized calibrations) can also be recovered using the probe analysis. We use this method to classify the backgrounds of wrapped M2-branes embedded in Calabi-Yau manifolds by specifying their calibrations.