We give an elementary analysis of the multiplicator group of the Galilei group in 1+2 dimensions G ↑ + . For a non-trivial multiplicator we give a list of all the corresponding projective unitary irreducible representations of G ↑ + .
We present a new point of view on the quantization of the massive
gravitational field, namely we use exclusively the quantum framework of the
second quantization. The Hilbert space of the many-gravitons system is a Fock
space ${\cal F}^{+}({\sf H}_{\rm graviton})$ where the one-particle Hilbert
space ${\sf H}_{graviton}$ carries the direct sum of two unitary irreducible
representations of the Poincar\'e group corresponding to two particles of mass
$m > 0$ and spins 2 and 0, respectively. This Hilbert space is canonically
isomorphic to a space of the type $Ker(Q)/Im(Q)$ where $Q$ is a gauge charge
defined in an extension of the Hilbert space ${\cal H}_{\rm graviton}$
generated by the gravitational field $h_{\mu\nu}$ and some ghosts fields
$u_{\mu}, \tilde{u}_{\mu}$ (which are vector Fermi fields) and $v_{\mu}$ (which
are vector field Bose fields.)
Then we study the self interaction of massive gravity in the causal
framework. We obtain a solution which goes smoothly to the zero-mass solution
of linear quantum gravity up to a term depending on the bosonic ghost field.
This solution depends on two real constants as it should be; these constants
are related to the gravitational constant and the cosmological constant. In the
second order of the perturbation theory we do not need a Higgs field, in sharp
contrast to Yang-Mills theory.Comment: 35 pages, no figur
We consider the supersymmetric vector multiplet in a purely quantum framework. We obtain some discrepancies with respect to the literature in the expression of the superpropagator and we prove that the model is consistent only for positive mass. The gauge structure is constructed purely deductive and leads to the necessity of introducing scalar ghost superfields, in analogy to the usual gauge theories. The construction of a consistent supersymmetric gauge theory based on the vector model depends crucially one the definition of gauge invariance. We find some significant difficulties to impose a supersymmetric gauge invariance condition for the usual expressions from the literature.
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