Algebras of nonlinear generalized functions were introduced in the 1980s by J.-F. Colombeau in
order to treat mathematical questions involving nonlinear operations, differentiation and
singularities. These algebras constitute an extension of both classical analysis and L. Schwartz`
distribution theory.
Colombeau algebras are employed successfully for the study of singular partial differential
equations, non-smooth differential geometry and singular Fourier integral operators. They have
found numerous applications e.g. in mathematical geophysics and general relativity.
Up to today, many aspects of this theory have been developed only for simplified variants of these
algebras, so-called special Colombeau algebras. These suffer from certain restrictions, for example
it is impossible to have a geometric (coordinate invariant) embedding of distributions into special
algebras. For this reason, a geometric theory of nonlinear generalized functions was developed
since the late 1990s in the context of full Colombeau algebras, which permit a coordiante-invariant
treatment of singular problems in a geometric context.
The development of this geometric theory of full Colombeau algebras in the most general case,
which is for generalized sections of vector bundles, was made possible only recently through the
introduction of a functional analytic approach which anchors Colombeau theory in the theoretical
foundations of distribution theory.
The aim of the present project is to further develop this functional analytic approach and hence
connect Colombeau theory to functional analytic methods which played only a minor role in it so
far. One major goal in this is the development of a structure theory for Colombeau algebras that
can explain the multitude of existing variants, their properties and their relations to each other,
and only in the context of which one can introduce and study important operations on nonlinear
generalized functions. As a result, methods will be developed for naturally adapting Colombeau
algebras to specific applications and placing them in closer relation to classical distribution theory.
The other main aim is to develop microlocal analysis and regularity theory for Colombeau algebras
based on this functional analytic approach. This way, more natural geometric approaches to this
field become possible, which gives new tools and methods for the analysis of nonlinear generalized
functions.