English

Path Integral Quantization of Volume

Probability 2017-06-06 v1

Abstract

A hyperlink is a finite set of non-intersecting simple closed curves in R×R3\mathbb{R} \times \mathbb{R}^3. Let RR be a compact set inside R3\mathbf{R}^3. The dynamical variables in General Relativity are the vierbein ee and a su(2)×su(2)\mathfrak{su}(2)\times\mathfrak{su}(2)-valued connection ω\omega. Together with Minkowski metric, ee will define a metric gg on the manifold. Denote VR(e)V_R(e) as the volume of RR, for a given choice of ee. The Einstein-Hilbert action S(e,ω)S(e,\omega) is defined on ee and ω\omega. We will quantize the volume of RR by integrating VR(e)V_R(e) against a holonomy operator of a hyperlink LL, disjoint from RR, and the exponential of the Einstein-Hilbert action, over the space of vierbein ee and su(2)×su(2)\mathfrak{su}(2)\times\mathfrak{su}(2)-valued connection ω\omega. Using our earlier work done on Chern-Simons path integrals in R3\mathbb{R}^3, we will write this infinite dimensional path integral as the limit of a sequence of Chern-Simons integrals. Our main result shows that the volume operator can be computed by counting the number of half-twists in the projected hyperlink, which lie inside RR. By assigning an irreducible representation of su(2)×su(2)\mathfrak{su}(2)\times\mathfrak{su}(2) to each component of LL, the volume operator gives the total kinetic energy, which comes from translational and angular momentum.

Cite

@article{arxiv.1706.01011,
  title  = {Path Integral Quantization of Volume},
  author = {Adrian P. C. Lim},
  journal= {arXiv preprint arXiv:1706.01011},
  year   = {2017}
}
R2 v1 2026-06-22T20:08:25.747Z