A novel renormalizable representation of the Yang-Mills theory

Abstract

For a generic gauge-invariant correlator < Q[Aμ]>A, we reformulate the standard D=4 Yang-Mills theory as a renormalizable system of two interacting fields aμ and Bμ which faithfully represent high- and low-energy degrees of freedom of the single gauge field Aμ in the original formulation. It opens a possibility to synthesize an infrared-nonsingular weak-coupling series, employed to integrate over aμ for a given background Bμ, with qualitatively different methods. These methods are to be applied to evaluate the resulting (after the aμ-integration) representation of < Q[Aμ]>A in terms of gauge-invariant generically non-local low-energy observables, like Wilson loops. The latter observables are averaged over Bμ with respect to a gauge-invariant Wilsonean effective action Seff[B]. To avoid a destructive dissipation between the high- and low-energy excitations, we implement a specific fine-tuning of the interaction between the pair of the fields: prior to the integration over Bμ, the expectation value <aμ>a vanishes, in the tree order of the loop-wise expansion, for an arbitrary configuration of Bμ.