Nonperturbative and Thermal Dynamics of Confined Fields in Dual QCD

Author:

Chandola H. C.1,Rawat Deependra Singh1ORCID,Yadav Dinesh1,Pandey H. C.2,Dehnen H.3

Affiliation:

1. Department of Physics (UGC-Centre of Advanced Study), Kumaun University, Nainital, India

2. Department of Physics, Birla Institute of Applied Sciences, Bhimtal, India

3. Fachbereich Physik, Universitat Konstanz, M677, 78457 Konstanz, Germany

Abstract

In order to study the detailed dynamics and associated nonperturbative features of QCD, a dual version of the color gauge theory based on a topologically viable homogeneous fibre bundle approach has been analysed taking into account its magnetic symmetry structure. In the dynamically broken phase of magnetic symmetry, the associated flux tube structure on a S2 sphere in the magnetically condensed state of the dual QCD vacuum has been analyzed for the profiles of the color electric field using flux quantization and stability conditions. The color electric field has its intimate association with the vector mode of the magnetically condensed QCD vacuum, and such field configurations have been analyzed to show that the color electric flux gets localized towards the poles for a large sphere case while it gets uniformly distributed for the small sphere case in the infrared sector of QCD. The critical flux tube densities have been computed for various couplings and are shown to be in agreement with that for lead-ion central collisions in the near infrared sector of QCD. The possible annihilation/unification of flux tubes under some typical flux tube density and temperature conditions in the magnetic symmetry broken phase of QCD has also been analyzed and shown to play an important role in the process of QGP formation. The thermal variation of the profiles of the color electic field is further investigated which indicates the survival of flux tubes even in the thermal domain that leads the possibility of the formation of some exotic states like QGP in the intermediate regime during the quark-hadron phase transition.

Funder

University Grants Commission

Publisher

Hindawi Limited

Subject

Nuclear and High Energy Physics

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