Vacua, Symmetries, and Higgsing of Chern-Simons Matter Theories

Abstract

Three-dimensional supersymmetric Chern-Simons Matter (CSM) theories typically preserve N=3 supersymmetry but can exhibit enhanced N=4 supersymmetry under special conditions. A detailed understanding of the moduli space of CSM theories, however, has remained elusive. This paper addresses this gap by systematically analysing the maximal branches of the moduli space of N=3 and N=4 CSM realised via Type IIB brane constructions. Firstly, for N=4 theories with Chern-Simons levels equal 1, the SL(2,Z) dualisation algorithm is employed to construct dual Lagrangian 3d N=4 theories without CS terms. This allows the full moduli space to be determined using quiver algorithms that compute Higgs and Coulomb branch Hasse diagrams and associated RG flows. Secondly, for N=4 theories with CS-levels greater 1, where SL(2,Z) dualisation does not yield CS-free Lagrangians, a new prescription is introduced to derive two magnetic quivers, MQA and MQB, whose Coulomb branches capture the maximal A and B branches of the original N=4 CSM theory. Applying the decay and fission algorithm to MQA/B then enables the systematic analysis of A/B branch RG flows and their geometric structures. Thirdly, for N=3 CSM theories, one magnetic quiver for each maximal (hyper-K\"ahler) branch is derived from the brane system. This provides an efficient and comprehensive characterisation of these previously scarcely studied features.

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