Anyonic physical observables and spin phase transition

A. Foerster; A. Foerster; A. M. Polyakov; B. Binegar; B. I. Halperin; B.-H. Lee; Bum-Hoon Lee; C. R. Hagen; C. R. Hagen; C. R. Hagen; C. R. Hagen; C. R. Hagen; D. Boyanovsky; D. Boyanovsky; D. M. Gitman; E. Fradkin; E. Fradkin; F. D. M. Haldane; F. Strocchi; F. Wilczek; G. W. Semenoff; G. W. Semenoff; G. W. Semenoff; H. Shin; Hyun Seok Yang; J. D. Bjorken; J. K. Kim; M. J. Bowick; Mu-In Park; P. A. M. Dirac; P. A. M. Dirac; P. K. Panigrahi; R. B. Laughlin; R. B. Laughlin; R. B. Laughlin; R. Banerjee; R. Banerjee; R. Banerjee; R. Jackiw; S. Deser; S. Deser; S. Deser; S. Forte; S. K. Paul; T. Matsuyama; T. Matsuyama; V. Kalmeyer; W.-T. Kim; X. G. Wen; X. G. Wen; Y. Aharonov; Y.-S. Wu

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Anyonic physical observables and spin phase transition

Abstract

The quantization of charged matter system coupled to Chern-Simons gauge fields is analyzed in a covariant gauge fixing, and gauge invariant physical anyon operators satisfying fractional statistics are constructed in a symmetric phase, based on Dirac's recipe performed on QED. This method provides us a definite way of identifying physical spectrums free from gauge ambiguity and constructing physical anyon operators under a covariant gauge fixing. We then analyze the statistical spin phase transition in a symmetry-broken phase and show that the Higgs mechanism transmutes an anyon satisfying fractional statistics into a canonical boson, a spin 0 Higgs boson or a topologically massive photon.Comment: 14 pages, added references, a few improvement

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