Lorentzian CR structures

Abstract: The mathematics of a 4-dimensional renormalizable generally covariant lagrangian model (with first order derivatives) is reviewed. The lorentzian CR manifolds are totally real submanifolds of 4(complex)-dimensional complex manifolds determined by four special conditions. The defining tetrad permits the definition of a class of lorentzian metrics which admit two geodetic and shear free congruences. These metrics permit the classification of the structures using the Weyl tensor and the Flaherty pseudo-complex structure. The Cartan procedure permits the definition of three relative invariants. Viewed as a pair of two hypersurface-type 3-dimensional CR structures, the lorentzian CR structures may be osculated on the basis of SU(1,2) group. An osculation on the basis of SU(2,2) group reveals the Poincare group which may be identified with the observed group in nature. Examples of static axially symmetric lorentzian CR structures are computed. For every lorentzian CR manifold, a class of Kaehler metrics of the ambient complex manifold is found, which induce the class of compatible lorentzian metrics on the submanifold. Then the lorentzian CR manifold becomes a lagrangian submanifold in the corresponding ambient (Kaehler) symplectic manifold. The lorentzian CR manifolds may be considered as dynamical processes in the context of the Einstein-Infeld-Hofman derivation of the equations of motion.