3 research outputs found
Pair of null gravitating shells II. Canonical theory and embedding variables
The study of the two shell system started in our first paper ``Pair of null
gravitating shells I'' (gr-qc/0112060) is continued. An action functional for a
single shell due to Louko, Whiting and Friedman is generalized to give
appropriate equations of motion for two and, in fact, any number of spherically
symmetric null shells, including the cases when the shells intersect. In order
to find the symplectic structure for the space of solutions described in paper
I, the pull back to the constraint surface of the Liouville form determined by
the action is transformed into new variables. They consist of Dirac
observables, embeddings and embedding momenta (the so-called Kucha\v{r}
decomposition). The calculation includes the integration of a set of coupled
partial differential equations. A general method of solving the equations is
worked out.Comment: 20 pages, Latex file using amstex, some references correcte
Pair of null gravitating shells III. Algebra of Dirac's observables
The study of the two-shell system started in ``Pair of null gravitating
shells I and II'' (gr-qc/0112060--061) is continued. The pull back of the
Liouville form to the constraint surface, which contains complete information
about the Poisson brackets of Dirac observables, is computed in the singular
double-null Eddington-Finkelstein (DNEF) gauge. The resulting formula shows
that the variables conjugate to the Schwarzschild masses of the intershell
spacetimes are simple combinations of the values of the DNEF coordinates on
these spacetimes at the shells. The formula is valid for any number of in- and
out-going shells. After applying it to the two-shell system, the symplectic
form is calculated for each component of the physical phase space; regular
coordinates are found, defining it as a symplectic manifold. The symplectic
transformation between the initial and final values of observables for the
shell-crossing case is written down.Comment: 26 pages, Latex file using amstex, some references correcte
Pair of null gravitating shells I. Space of solutions and its symmetries
The dynamical system constituted by two spherically symmetric thin shells and
their own gravitational field is studied. The shells can be distinguished from
each other, and they can intersect. At each intersection, they exchange energy
on the Dray, 't Hooft and Redmount formula. There are bound states: if the
shells intersect, one, or both, external shells can be bound in the field of
internal shells. The space of all solutions to classical dynamical equations
has six components; each has the trivial topology but a non trivial boundary.
Points within each component are labeled by four parameters. Three of the
parameters determine the geometry of the corresponding solution spacetime and
shell trajectories and the fourth describes the position of the system with
respect to an observer frame. An account of symmetries associated with
spacetime diffeomorphisms is given. The group is generated by an infinitesimal
time shift, an infinitesimal dilatation and a time reversal.Comment: 28 pages, 9 figure included in the text, Latex file using amstex,
epic and graphi