Parametrization of holonomy-flux phase space in the Hamiltonian formulation of SO(N) gauge field theory with SO(D+1) loop quantum gravity as an exemplification

Abstract

The SO(N) Yang-Mills gauge theory is concerned since it can be used to explore the new theory beyond the standard model of particle physics and the higher dimensional loop quantum gravity. The canonical formulation and loop quantization of SO(N) Yang-Mills theory suggest a discrete SO(N) holonomy-flux phase space, and the properties of the critical quantum algebras in the loop quantized SO(N) Yang-Mills theory are encoded in the symplectic structure of this SO(N) holonomy-flux phase space. With the SO(D+1) loop quantum gravity as an exemplification of loop quantized SO(N) Yang-Mills gauge theory, we introduce a new parametrization of the SO(D+1) holonomy-flux phase space in this paper. Moreover, the symplectic structure of the SO(D+1) holonomy-flux phase space are analyzed in terms of the parametrization variables. Comparing to the Poisson algebras among the SO(D+1) holonomy-flux variables, it is shown that the Poisson algebras among the parametrization variables take a clearer formulation, i.e., the Lie algebras of so(D+1) and the Poisson algebras between angle-length pairs.