Non-Renormalization Theorems in Non-Renormalizable Theories
Abstract
A perturbative non-renormalization theorem is presented that applies to general supersymmetric theories, including non-renormalizable theories in which the ∫ d2θ integrand is an arbitrary gauge-invariant function F(,W) of the chiral superfields and gauge field-strength superfields W, and the ∫ d4θ-integrand is restricted only by gauge invariance. In the Wilsonian Lagrangian, F(,W) is unrenormalized except for the one-loop renormalization of the gauge coupling parameter, and Fayet-Iliopoulos terms can be renormalized only by one-loop graphs, which cancel if the sum of the U(1) charges of the chiral superfields vanishes. One consequence of this theorem is that in non-renormalizable as well as renormalizable theories, in the absence of Fayet-Iliopoulos terms supersymmetry will be unbroken to all orders if the bare superpotential has a stationary point.
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