Hamiltonian Analysis of Gauged CP1 Model, the Hopf term, and fractional spin
Abstract
Recently it was shown by Cho and Kimm that the gauged CP1 model, obtained by gauging the global SU(2) group and adding a corresponding Chern-Simons term, has got its own soliton. These solitons are somewhat distinct from those of pure CP1 model as they cannot always be characterised by π2(CP1)=Z. In this paper, we first carry out a detailed Hamiltonian analysis of this gauged CP1 model. This reveals that the model has only SU(2) as the gauge invariance, rather than SU(2) × U(1). The U(1) gauge invariance of the original (ungauged) CP1 model is actually contained in the SU(2) group itself. Then we couple the Hopf term associated to these solitons and again carry out its Hamiltonian analysis. The symplectic structures, along with the structures of the constraints of these two models (with or without Hopf term) are found to be essentially the same. The model with a Hopf term is shown to have fractional spin which, when computed in the radiation gauge, is found to depend not only on the soliton number N, but also on the nonabelian charge. We then carry out a reduced (partially) phase space analysis in a different physical sector of the model where the degrees of freedom associated with the CP1 fields are transformed away. The model now reduces to a U(1) gauge theory with two Chern-Simons gauge fields getting mass-like terms and one remaining massless. In this case the fractional spin is computed in terms of the dynamical degrees of freedom and shown to depend purely on the charge of the surviving abelian symmetry. Although this reduced model is shown to have its own solitonic configuration, it turns out to be trivial.
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