A gauge-invariant UV-IR mixing and the corresponding phase transition for U(1) fields on the fuzzy sphere

Castro-Villarreal, P. and Delgadillo-Blando, Rodrigo and Ydri, Badis (2004) A gauge-invariant UV-IR mixing and the corresponding phase transition for U(1) fields on the fuzzy sphere. (Preprint)

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Abstract

From a string theory point of view the most natural gauge action on the fuzzy sphere S_L^2 is the Alekseev-Recknagel-Schomerus action which is a particular combination of the Yang-Mills action and the Chern-Simons term. The differential calculus on the fuzzy sphere is 3−dimensional and thus the field content of this model consists of a 2-dimensional gauge field together with a scalar fluctuation normal to the sphere. For U(1) gauge theory we compute the quadratic effective action and shows explicitly that the tadpole diagrams and the vacuum polarization tensor contain a gauge-invariant UV-IR mixing in the continuum limit L→∞ where L is the matrix size of the fuzzy sphere. In other words the quantum U(1) effective action does not vanish in the commutative limit and a noncommutative anomaly survives. We compute the scalar effective potential and prove the gauge-fixing-independence of the limiting model L = ∞ and then show explicitly that the one-loop result predicts a first order phase transition which was observed recently in simulation. The one-loop result for the U(1) theory is exact in this limit. It is also argued that if we add a large mass term for the scalar mode the UV-IR mixing will be completely removed from the gauge sector. It is found in this case to be confined to the scalar sector only. This is in accordance with the large L analysis of the model. Finally we show that the phase transition becomes harder to reach starting from small couplings when we increase M.

Item Type: Article
Divisions: School of Theoretical Physics > Preprints
Date Deposited: 18 Jul 2018 09:06
Last Modified: 18 Jul 2018 09:06
URI: http://dair.dias.ie/id/eprint/633

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