English

Partition Function for (2+1)-Dimensional Einstein Gravity

General Relativity and Quantum Cosmology 2011-09-09 v2

Abstract

Taking (2+1)-dimensional pure Einstein gravity for arbitrary genus gg as a model, we investigate the relation between the partition function formally defined on the entire phase space and the one written in terms of the reduced phase space. In particular the case of g=1g=1 is analyzed in detail. By a suitable gauge-fixing, the partition function ZZ basically reduces to the partition function defined for the reduced system, whose dynamical variables are (τA,pA)(\tau^A, p_A). [The τA\tau^A's are the Teichm\"uller parameters, and the pAp_A's are their conjugate momenta.] As for the case of g=1g=1, we find out that ZZ is also related with another reduced form, whose dynamical variables are (τA,pA)(\tau^A, p_A) and (V,σ)(V, \sigma). [Here σ\sigma is a conjugate momentum to 2-volume VV.] A nontrivial factor appears in the measure in terms of this type of reduced form. The factor turns out to be a Faddeev-Popov determinant coming from the time-reparameterization invariance inherent in this type of formulation. Thus the relation between two reduced forms becomes transparent even in the context of quantum theory. Furthermore for g=1g=1, a factor coming from the zero-modes of a differential operator P1P_1 can appear in the path-integral measure in the reduced representation of ZZ. It depends on the path-integral domain for the shift vector in ZZ: If it is defined to include kerP1\ker P_1, the nontrivial factor does not appear. On the other hand, if the integral domain is defined to exclude kerP1\ker P_1, the factor appears in the measure. This factor can depend on the dynamical variables, typically as a function of VV, and can influence the semiclassical dynamics of the (2+1)-dimensional spacetime. These results shall be significant from the viewpoint of quantum gravity.

Keywords

Cite

@article{arxiv.gr-qc/9609052,
  title  = {Partition Function for (2+1)-Dimensional Einstein Gravity},
  author = {Masafumi Seriu},
  journal= {arXiv preprint arXiv:gr-qc/9609052},
  year   = {2011}
}

Comments

21 pages. To appear in Physical Review D. The discussion on the path-integral domain for the shift vector has been added