10 research outputs found
Variational and Geometric Structures of Discrete Dirac Mechanics
In this paper, we develop the theoretical foundations of discrete Dirac
mechanics, that is, discrete mechanics of degenerate Lagrangian/Hamiltonian
systems with constraints. We first construct discrete analogues of Tulczyjew's
triple and induced Dirac structures by considering the geometry of symplectic
maps and their associated generating functions. We demonstrate that this
framework provides a means of deriving discrete Lagrange-Dirac and nonholonomic
Hamiltonian systems. In particular, this yields nonholonomic Lagrangian and
Hamiltonian integrators. We also introduce discrete
Lagrange-d'Alembert-Pontryagin and Hamilton-d'Alembert variational principles,
which provide an alternative derivation of the same set of integration
algorithms. The paper provides a unified treatment of discrete Lagrangian and
Hamiltonian mechanics in the more general setting of discrete Dirac mechanics,
as well as a generalization of symplectic and Poisson integrators to the
broader category of Dirac integrators.Comment: 26 pages; published online in Foundations of Computational
Mathematics (2011
Quantum corrections for spinning particles in de Sitter
We compute the one-loop quantum corrections to the gravitational potentials of a spinning point particle in a de Sitter background, due to the vacuum polarisation induced by conformal fields in an effective field theory approach. We consider arbitrary conformal field theories, assuming only that the theory contains a large number N of fields in order to separate their contribution from the one induced by virtual gravitons. The corrections are described in a gauge-invariant way, classifying the induced metric perturbations around the de Sitter background according to their behaviour under transformations on equal-time hypersurfaces. There are six gauge-invariant modes: two scalar Bardeen potentials, one transverse vector and one transverse traceless tensor, of which one scalar and the vector couple to the spinning particle. The quantum corrections consist of three different parts: a generalisation of the flat-space correction, which is only significant at distances of the order of the Planck length; a constant correction depending on the undetermined parameters of the renormalised effective action; and a term which grows logarithmically with the distance from the particle. This last term is the most interesting, and when resummed gives a modified power law, enhancing the gravitational force at large distances. As a check on the accuracy of our calculation, we recover the linearised Kerr-de Sitter metric in the classical limit and the flat-space quantum correction in the limit of vanishing Hubble constant
A Note on a Variational Formulation of Electrodynamics
We present a variational formulation of electrodynamics using de Rham even and odd differential forms. By relying on a variational principle more complete than the Hamilton principle, our formulation leads to field equations with external sources and permits the derivation of the constitutive relations
Local algebra bundles and α-jets of mappings
We present the functor associated with a local algebra bundle and the
differential structure of the double fibre bundle it produces when applied
to a differential manifold