Partition Function for (2+1)-Dimensional Einstein Gravity
Abstract
Taking (2+1)-dimensional pure Einstein gravity for arbitrary genus 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 is analyzed in detail. By a suitable gauge-fixing, the partition function basically reduces to the partition function defined for the reduced system, whose dynamical variables are . [The 's are the Teichm\"uller parameters, and the 's are their conjugate momenta.] As for the case of , we find out that is also related with another reduced form, whose dynamical variables are and . [Here is a conjugate momentum to 2-volume .] 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 , a factor coming from the zero-modes of a differential operator can appear in the path-integral measure in the reduced representation of . It depends on the path-integral domain for the shift vector in : If it is defined to include , the nontrivial factor does not appear. On the other hand, if the integral domain is defined to exclude , the factor appears in the measure. This factor can depend on the dynamical variables, typically as a function of , 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