Non-Commutative Differential Geometry on Discrete Space M4× ZN and Gauge Theory

Abstract

The algebra of non-commutative differential geometry (NCG) on the discrete space M4× ZN previously proposed by the present author is improved to give the consistent explanation of the generalized gauge field as the generalized connection on M4× ZN. The nilpotency of the generalized exterior derivative d is easily proved. The matrix formulation where the generalized gauge field is denoted in matrix form is shown to have the same content with the ordinary formulation using d, which helps us understand the implications of the algebraic rules of NCG on M4× ZN. The Lagrangian of spontaneously broken gauge theory which has the extra restriction on the coupling constant of the Higgs potential is obtained by taking the inner product of the generalized field strength. The covariant derivative operating on the fermion field determines the parallel transformation on M4× ZN, which confirms that the Higgs field is the connection on the discrete space. This implies that the Higgs particle is a gauge particle on the same footing as the weak bosons. Thus, it is expected that the mass relation mH=43mWθW proposed by the present author holds without any correction in the same way as the mass relation mW=mZθW. The Higgs kinetic and potential terms are regarded as the curvatures on M4× ZN.