From Noncommutative Kinematics to \(U(1)\) Gauge Theory: A Family of Spectral Triples with Localized Gauge Perturbations

Abstract

We construct locally compact non-unital spectral triples for a noncommutative planar system determined by a fixed nondegenerate irreducible unitary sector of the kinematical symmetry group \(GNC\). The sector is labelled by central parameters \((0,0,B0)\), with \(0,0,B0≠0\) and \(0-0B0≠0\). For this sector, the triples \(( S_0,0,B0, H, Dr,s_0,0,B0)\) form an even two-parameter family indexed by \((r,s)\), and different choices of \((r,s)\) give unitarily equivalent realizations. The unperturbed Dirac operators have Landau-type spectral levels of infinite multiplicity; hence local compactness, rather than compact resolvent, is the relevant analytic condition. We then identify the represented algebra \(π( S_0,0,B0)\) with the effective Moyal Fréchet \(\)-algebra with deformation parameter \(eff =01-0B0/0.\) For each star-product realization parameter \(\), this yields spectral triples over the involutive Moyal algebra \( A_eff,\). External \(U(1)_eff,\)-gauge potentials are incorporated by localizing the affine gauge potentials with smooth cutoffs. The resulting bounded self-adjoint perturbations \(BR()\) define Dirac operators \(DR,r,s=D\,r,s+BR().\) Finally, as \(R∞\), these operators converge in the strong resolvent sense to a self-adjoint limiting operator \(D∞\), the closure of the formal minimally coupled operator. Thus the finite-cutoff triples rigorously approximate the limiting minimally coupled Dirac operator associated with the fixed nondegenerate \(GNC\)-sector.