Modified General Relativity and quantum theory in curved spacetime

Abstract

With appropriate modifications, the multi-spin Klein-Gordon (KG) equation of quantum field theory can be adapted to curved spacetime for spins 0,1,1/2. The associated particles in the microworld then move as a wave at all spacetime coordinates. From the existence in a Lorentzian spacetime of a line element field (Xβ,-Xβ) , the spin-1 KG equation ∇μ∇μXβ=k2Xβ is derived from an action functional involving Xβ and its covariant derivative. The spin-0 KG equation and the KG equation of the outer product of a spin-1/2 Dirac spinor and its Hermitian conjugate are then constructed. Thus, Xβ acts as a fundamental quantum vector field. The symmetric part of the spin-1 KG equation, αβ, is the Lie derivative of the metric. That links the multi-spin Klein-Gordon equation to Modified General Relativity (MGR) through its energy-momentum tensor of the gravitational field. From the invariance of the action functionals under the diffeomorphism group Diff(M), which is not restricted to the Lorentz group, αβ can instantaneously transmit information along Xβ . That establishes the concept of entanglement within a Lorentzian formalism. The respective local/nonlocal characteristics of MGR and quantum theory no longer present an insurmountable problem to unify the theories.