Abstract
The canonical formulation of general relativity (GR) is based on decomposition space–time manifold M into R × Σ , where R represents the time, and Ksi is the three-dimensional space-like surface. This decomposition has to preserve the invariance of GR, invariance under general coordinates, and local Lorentz transformations. These symmetries are associated with conserved currents that are coupled to gravity. These symmetries are studied on a three dimensional space-like hypersurface Σ embedded in a four-dimensional space–time manifold. This implies continuous symmetries and conserved currents by Noether’s theorem on that surface. We construct a three-form E i ∧ D A i (D represents covariant exterior derivative) in the phase space ( E i a , A a i ) on the surface Σ , and derive an equation of continuity on that surface, and search for canonical relations and a Lagrangian that correspond to the same equation of continuity according to the canonical field theory. We find that Σ i 0 a is a conjugate momentum of A a i and Σ i a b F a b i is its energy density. We show that there is conserved spin current that couples to A i , and show that we have to include the term F μ ν i F μ ν i in GR. Lagrangian, where F i = D A i , and A i is complex S O ( 3 ) connection. The term F μ ν i F μ ν i includes one variable, A i , similar to Yang–Mills gauge theory. Finally we couple the connection A i to a left-handed spinor field ψ , and find the corresponding beta function.
Highlights
Gravity can be formulated based on gauge theory by gauging the Lorentz group SO(3, 1) [1]
We need to fix some base space and consider that the Lorentz group SO(3, 1) acts locally on Lorentz frames which are regarded as a frame bundle over a fixed base space
By that we have two symmetries; invariance under continuous transformations of local Lorentz frame, SO(3, 1) group, and invariance under diffeomorphism of the space–time M, which is originally considered as a base space [2]
Summary
Gravity can be formulated based on gauge theory by gauging the Lorentz group SO(3, 1) [1]. Let us write dt∂t L1 ( gab ) = (Σ(σ a ), dθ ), where (Σ, V ) is a projection of V ∈ ∧4 Tp∗ M onto a surface Σ, the inner product of V with tangent basis in Tp Σ, defined below in Equation (17), and θ is three-form in the phase space ( Ei , ω ij ) on Σ(σ a ). Using the projection in Equation (12), we rewrite θ in the complex phase space ( Eia , Aia ) as i θ ( E, ω, Σ(σ a )) = (16πG )−1/2 ε abc Eic Fab ( A)ed σ, where we take in consideration only the first part, the second is obtained by taking the Hermitian conjugate. This Lagrangian is similar to the Plebanisky Lagrangian, but it is not multiplied by the imaginary number i and does not include the cosmological constant term
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