Relation between the guessed and the derived super-Hamiltonians for spherically symmetric shells
Abstract
The Hamiltonian dynamics of spherically symmetric massive thin shells in the general relativity is studied. Two different constraint dynamical systems representing this dynamics have been described recently; the relation of these two systems is investigated. The symmetry groups of both systems are found. New variables are used, which among other things simplify the complicated system a great deal. The systems are reduced to presymplectic manifolds Gamma1 and Gamma2, lest non-physical aspects like gauge fixings or embeddings in extended phase spaces complicate the line of reasoning. The following facts are shown. Gamma1 is three- and Gamma2 is five-dimensional; the description of the shell dynamics by Gamma1 is incomplete so that some measurable properties of the shell cannot be predicted. Gamma1 is locally equivalent to a subsystem of Gamma2 and the corresponding local morphisms are not unique, due to the large symmetry group of Gamma2. Some consequences for the recent extensions of the quantum shell dynamics through the singularity are discussed.
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