Self-dual non-Abelian N = 1 tensor multiplet in D = 2+ 2 dimensions

TL;DR

This paper constructs a self-dual non-Abelian N=1 supersymmetric tensor multiplet in 2+2 dimensions, incorporating duality relations, Chern-Simons terms, and superspace reformulation, with applications to integrable systems.

Contribution

It introduces a novel self-dual non-Abelian tensor multiplet in 2+2 dimensions, including duality symmetries and Chern-Simons couplings, and connects to integrable systems.

Findings

Successfully formulated the multiplet with duality relations.

Reformulated results in superspace for confirmation.

Embedded KdV flows into the supersymmetric system.

Abstract

We present a self-dual non-Abelian N=1 supersymmetric tensor multiplet in D=2+2 space-time dimensions. Our system has three on-shell multiplets: (i) The usual non-Abelian Yang-Mills multiplet (A_\mu{}^I, \lambda{}^I) (ii) A non-Abelian tensor multiplet (B_{\mu\nu}{}^I, \chi^I, \varphi^I), and (iii) An extra compensator vector multiplet (C_\mu{}^I, \rho^I). Here the index I is for the adjoint representation of a non-Abelian gauge group. The duality symmetry relations are G_{\mu\nu\rho}{}^I = - \epsilon_{\mu\nu\rho}{}^\sigma \nabla_\sigma \varphi^I, F_{\mu\nu}{}^I = + (1/2) \epsilon_{\mu\nu}{}^{\rho\sigma} F_{\rho\sigma}{}^I, and H_{\mu\nu}{}^I = +(1/2) \epsilon_{\mu\nu}{\rho\sigma} H_{\rho\sigma}{}^I, where G and H are respectively the field strengths of B and C. The usual problem with the coupling of the non-Abelian tensor is avoided by non-trivial Chern-Simons terms in the field strengths G_{\mu\nu\rho}{}^I and H_{\mu\nu}{}^I. For an independent confirmation, we re-formulate the component results in superspace. As applications of embedding integrable systems, we show how the {\cal N} = 2, r = 3 and {\cal N} = 3, r = 4 flows of generalized Korteweg-de Vries equations are embedded into our system.