Gravity as an SU(1,1) gauge theory in four dimensions

Abstract

We start with the Hamiltonian formulation of the first order action of pure gravity with a full sl(2, C) internal gauge symmetry. We make a partial gauge-fixing which reduces sl(2, C) to its sub-algebra su(1,1). This case corresponds to a splitting of the space-time M= × R where inherits an arbitrary Lorentzian metric of signature (-,+,+). Then, we find a parametrization of the phase space in terms of an su(1,1) commutative connection and its associated conjugate electric field. Following the techniques of Loop Quantum Gravity, we start the quantization of the theory and we consider the kinematical Hilbert space on a given fixed graph whose edges are colored with unitary representations of su(1,1). We compute the spectrum of area operators acting of the kinematical Hilbert space: we show that space-like areas have discrete spectra, in agreement with usual su(2) Loop Quantum Gravity, whereas time-like areas have continuous spectra. We conclude on the possibility to make use of this formulation of gravity to construct a holographic description of black holes in the framework of Loop Quantum Gravity.