Decoupling of Heavy Kaluza-Klein Modes In Models With Five-Dimensional Scalar Fields

Abstract

We investigate the decoupling of heavy Kaluza-Klein modes in φ4 theory and scalar QED with space-time topology R3,1 × S1. We calculate the effective action due to integrating out heavy KK modes. We construct generalized RGE's for the couplings with respect to the compactification scale M. With the solutions to the RGE's we find the M-scale dependence of the effective theory due to higher dimensional quantum effects. We find that the heavy modes decouple in φ4 theory, but do not decouple in scalar QED. This is due to the zero mode of the 5-th component A5 of the 5-d gauge field. Because A5 is a scalar under 4-d Lorentz transformations, there is no gauge symmetry protecting it from getting mass and A54 interaction terms after loop corrections. In light of these unpleasant features, we explore S1/Z2 compactifications, which eliminate A5, allowing for the heavy modes to decouple at low energies. We also explore the possibility of decoupling by including higher dimensional operators. It is found that this is possible, but a high degree of fine tuning is required.