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Vector supersymmetry of Chern-Simons theory at finite temperature

Abstract

The existence of the vector supersymmetry is analysed within the context of the finite temperature Chern-Simons theory.


Vector supersymmetry of Chern-Simons theory at finite temperature

D.G.G. Sasaki,

Centro Brasileiro de Pesquisas Físicas,

Rua Xavier Sigaud 150, 22290-180, Rio de Janeiro, RJ, Brazil

S.P. Sorella, and V.E.R.Lemes

Departamento de Física Teórica

Instituto de Física, UERJ

Rua São Francisco Xavier, 524

20550-013 Maracanã, Rio de Janeiro, Brazil

Received 1 December, 1999

The existence of the vector supersymmetry is analysed within the context of the finite temperature Chern-Simons theory.

I Introduction

Since many years the topological three-dimensional Chern-Simons [1, 2] theory is the source of continuous and renewed interests, with many applications going from pure field theory to condensed matter physics. The Chern-Simons gauge model has been the first example of a topological field theory of the Schwarz type, allowing for the computation of several topological invariants in knots theory [1]. It is a remarkable fact that these computations can be performed within the standard perturbation theory [3]. Moreover, the Chern-Simons provides an example of a fully ultraviolet finite field theory, with vanishing b-function and field anomalous dimensions [4]. This feature relies on the existence of an additional global invariance of the Chern-Simons action which shows up only after the introduction of the gauge fixing and of the corresponding Faddeev-Popov ghost term. This further symmetry is known as vector supersymmetry [5, 2] since its generators carry a Lorentz index and, together with the BRST symmetry, give rise to a supersymmetric algebra of the Wess-Zumino type. It worth mentioning that the nonzero temperature version of the Chern-Simons action is also available [6] and turns out to play an important role in the applications of three-dimensional gauge theories to finite temperature effects. Therefore, it seems naturally to ask ourselves if the vector supersymmetry is still present in the case of a nonzero temperature. This is the aim of the present letter. In particular, we shall be able to show that this question can be answered in the affirmative. In this sense, the fully quantized Chern-Simons action can be considered as an example of a superymmetric field theory at finite temperature. The paper is organized as follows. In Sect.2 we present the finite temperature Chern-Simons action and we analyse the existence of the aforementioned supersymmetry. Sect.3 will be devoted to the study of some consequences and to the conclusion.

II Finite temperature Chern-Simons action

In order to analyse the properties of the Chern-Simons action at finite temperature let us first recall the supersymmetric structure of the zero temperature case. Adopting the Landau gauge, for the fully quantized Chern-Simons action we have

Expression (II.1) is left invariant by the following nilpotent BRST transformations

In addition, the action (II.2) is known [5, 2] to possess a further rigid invariance whose generators dm carry a vector index, i.e.

and, together with the BRST transformations, obey the following relations

which, closing on-shell on the space-time translations, give rise to a supersymmetric algebra of the Wess-Zumino type.

Concerning now the nonzero temperature case, for the quantized Chern-Simons action in the imaginary time formalism [6], we obtain

where b stands for the inverse of the temperature T. As is well known, all fields h = (A, c, , b) are required to obey periodic boundary conditions along the compactified direction t [7], namely

where the øn are the so-called Matsubara frequencies [7]

We emphasize here that the ghost fields c, , although being anticommuting variables, have to be periodic in t. As we shall see in the following, this property will be crucial for the existence of a supersymmetric structure at nonzero temperature. In order to write down the finite temperature Chern-Simons action in terms of the Matsubara modes hn, we identify the t-direction with the x3 variable and we introduce the following useful two-dimensional notation

Thus, for the action we obtain

where

In terms of the Matsubara modes, the BRST transformations (II.2) read

Moreover, it can be checked that the nonzero temperature action (II.9) is left invariant by the further following rigid transformations da, d, namely

and

The generators da, d, give rise, together with the BRST operator s, to the following algebraic relations

We see therefore that the supersymmetric structure (II.4) of the zero temperature Chern-Simons persists also in the case of a nonvanishing temperature. In particular, it is easily recognized that the operator d of eqs.(II.13) corresponds to the generator dt of eqs. (II.3) along the compactified direction t = x3. It is also worth underlining here that the existence of a nonzero temperature supersymmetric algebra relies on the periodic boundary conditions required for the Faddeev-Popov ghosts c, . As is well known, this property follows from the gauge invariance of the nonzero temperature action ST. Moreover, the supersymmetry turns out to be crucial in order to ensure that no physical excitations show up in the nonzero temperature case, as it will be discussed in the next section. In other words, the nonzero temperature Chern-Simons action remains a topological theory, with no local physical degrees of freedom.

III Conclusion

It has been already underlined that in the zero temperature case the existence of the vector supersymmetry is deeply related to the topological nature of the Chern-Simons term. We recall in fact that the supersymmetry shows up only after the introduction of the ghost fields. As a consequence, it follows that the contributions coming from the propagating components of the gauge field are exactly compensated by those corresponding to the ghosts, resulting in the well known ultraviolet finiteness of the theory. This means that the are no local physical degrees of freedom, i.e. that the theory is topological. The existence of a supersymmetric structure in the case of nonzero temperature suggests a similar behaviour for the finite temperature version of the Chern-Simons. This fact can be easily confirmed in the abelian case by showing that the partition function turns out to be independent from the temperature, implying the vanishing of all relevant thermodynamic quantities. Let us compute in fact the partition function for the abelian Maxwell-Chern-Simons action

with

We have introduced a constant g in order to take into account the Maxwell term. Of course, the pure Chern-Simons contribution is recovered in the limit g ® 0. For the free energy we obtain the following result

where L2 stands for the two-dimensional area. Obviously, expression (III.17) does not depend from in the limit g ® 0. Again, there is a complete compensation between the ghost and the gauge sectors, as expected from the existence of the supersymmetry. The analysis of the ultraviolet finiteness of the nonabelian finite temperature case as well as the computation of the vacuum expectation value of Polyakov loops are under investigation.

Acknowledgements

The Conselho Nacional de Desenvolvimento Científico e Tecnólgico CNPq-Brazil, the Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro (Faperj) and the SR2-UERJ are acknowledged for the financial support.

References

[1] E. Witten, Comm. Math. Phys. 121, 351 (1989).

[2] D. Birmingham, M. Blau, M. Rakowski and G. Thompson, Phys. Rep. 209, 129 (1991).

[3] E. Guadagnini, The link invariants of the Chern-Simons field theory: new developments in topological quantum field theory, de Gruyter (1993), Berlin, Germany.

[4] F. Delduc, C. Lucchesi, O. Piguet and S.P. Sorella, Nucl. Phys. B 346, 313 (1990).

[5] F. Delduc, F. Gieres and S.P. Sorella, Phys. Lett. B 225, 367 (1998).

[6] C.D. Fosco, G.L. Rossini and F.A. Schaposnik, Phys. Rev. D59, 085012 (1999); I.J.R. Aitchison and C.D. Fosco, Phys. Rev. D57, 171 (1998).

[7] J. L. Kapusta, Finite-temperature field theory, Cambridge University Press, 1989.

  • [1] E. Witten, Comm. Math. Phys. 121, 351 (1989).
  • [2] D. Birmingham, M. Blau, M. Rakowski and G. Thompson, Phys. Rep. 209, 129 (1991).
  • [3] E. Guadagnini, The link invariants of the Chern-Simons field theory: new developments in topological quantum field theory, de Gruyter (1993), Berlin, Germany.
  • [4] F. Delduc, C. Lucchesi, O. Piguet and S.P. Sorella, Nucl. Phys. B 346, 313 (1990).
  • [5] F. Delduc, F. Gieres and S.P. Sorella, Phys. Lett. B 225, 367 (1998).
  • [6] C.D. Fosco, G.L. Rossini and F.A. Schaposnik, Phys. Rev. D59, 085012 (1999);
  • I.J.R. Aitchison and C.D. Fosco, Phys. Rev. D57, 171 (1998).
  • [7] J. L. Kapusta, Finite-temperature field theory, Cambridge University Press, 1989.

Publication Dates

  • Publication in this collection
    07 Jan 2002
  • Date of issue
    June 2000

History

  • Received
    01 Dec 1999
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