Supersymmetric Proximity

Abstract

I argue that a certain perturbative proximity exists between some supersymmetric and non-supersymmetric theories (namely, pure Yang-Mills and adjoint QCD with two flavors, adjQCDNf=2). I start with N=2 super-Yang-Mills theory built of two N=1 superfields: vector and chiral. In N=1 language the latter presents matter in the adjoint representation of SU(N). Then I convert the matter superfield into a " phantom" one (in analogy with ghosts), breaking N=2 down to N=1. The global SU(2) acting between two gluinos in the original theory becomes graded. Exact results in thus deformed theory allows one to obtain insights in certain aspects of non-supersymmetric gluodynamics. In particular, it becomes clear how the splitting of the β function coefficients in pure gluodynamics, β1 =(4 - 13 )N and β2= (6- 13)N2, occurs. Here the first terms in the braces (4 and 6, always integers) are geometry-related while the second terms (- 13 in both cases) are bona fide quantum effects. In the same sense adjQCDNf=2 is close to N=2 SYM. Thus, I establish a certain proximity between pure gluodynamics and adjQCDNf=2 with supersymmetric theories. (Of course, in both cases we loose all features related to flat directions and Higgs/Coulomb branches in N=2.) As a warmup exercise I use this idea in 2D CP(1) sigma model with N=(2,2) supersymmetry, through the minimal heterotic N=(0,2) bosonic CP(1).