English

Counting surface states in the loop quantum gravity

General Relativity and Quantum Cosmology 2009-10-28 v3

Abstract

We adopt the point of view that (Riemannian) classical and (loop-based) quantum descriptions of geometry are macro- and micro-descriptions in the usual statistical mechanical sense. This gives rise to the notion of geometrical entropy, which is defined as the logarithm of the number of different quantum states which correspond to one and the same classical geometry configuration (macro-state). We apply this idea to gravitational degrees of freedom induced on an arbitrarily chosen in space 2-dimensional surface. Considering an `ensemble' of particularly simple quantum states, we show that the geometrical entropy S(A)S(A) corresponding to a macro-state specified by a total area AA of the surface is proportional to the area S(A)=αAS(A)=\alpha A, with α\alpha being approximately equal to 1/16πlp21/16\pi l_p^2. The result holds both for case of open and closed surfaces. We discuss briefly physical motivations for our choice of the ensemble of quantum states.

Keywords

Cite

@article{arxiv.gr-qc/9603025,
  title  = {Counting surface states in the loop quantum gravity},
  author = {Kirill V. Krasnov},
  journal= {arXiv preprint arXiv:gr-qc/9603025},
  year   = {2009}
}

Comments

This paper is a substantially modified version of the paper `The Bekenstein bound and non-perturbative quantum gravity'. Although the main result (i.e. the result of calculation of the number of quantum states that correspond to one and the same area of 2-d surface) remains unchanged, it is presented now from a different point of view. The new version contains a discussion both of the case of open and closed surfaces, and a discussion of a possibility to generalize the result obtained considering arbitrary surface quantum states. LaTeX, 21 pages, 6 figures added