5B1457 Non-linear wave equations, Seminar course II, 5 points, Spring 2005.



A Swedish version of this page is available here

Teacher: Hans Ringström,  hansr@math.kth.se, rum 3629, Lindstedsv. 25, 790 66 75.

A short description of the course is available in Swedish in pdf and ps form.

Litterature: The literature will consist of material that I shall hand out during the course. The complete notes are available in pdf and ps form.

Errata: Unfortunately, there are some errors in the above course notes. A list of errata can be found here. If you find any errors in the notes, please contact me (Hans Ringström: hansrkth.se).

Additional references: A good book on the subject is The level of this book is however higher than what I intend for the course. There are also interesting lecture notes on a course given by Sigmund Selberg on non-linear wave equations at John Hopkins University. The interested reader is referred to his homepage. Again, the level of these notes is higher than what I intend for the course.

Examination: The examination will be in the form of homework problems that will be handed out during the course.

Time: The lectures will be given in room 3733, Matematikinstitutionen, Lindstedtsvägen 25, floor 4. Tuesdays 10:15-12:00.

Non-linear wave equations in General Relativity
About 50 years ago it was shown that one can formulate Einstein's equations of General Relativity as an initial value problem. One specifies data at one moment in time and then one reconstructs the spacetime from this information. Needless to say, it is very difficult to do this in general. Consequently, it is natural to make additional assumptions before trying to deal with the problem. In cosmology for instance, one standard assumption is that the universe is spatially homogeneous and isotropic. What this means is that at a fixed time, the universe looks the same at different points in space (spatial homogeneity) and it also looks the same in different directions (isotropy). When one has made these stringent assumptions the only freedom left is a scale factor, and Einstein's equations reduce to an ordinary differential equation for the scale factor. It is of some interest to try to relax these conditions. If one first drops the isotropy condition, the mathematical problem one ends up with is a system of ordinary differential equations. If one also relaxes the condition of spatial homogeneity, one is confronted with non-linear wave equations. One can still demand that there be no spatial variation in certain spatial directions, so that one gets non-linear wave equations in 1+1 dimensions, 2+1 dimensions or 3+1 dimensions depending on the symmetry
assumptions (when I write 2+1 dimensions I mean that there are 2 spatial dimensions and 1 time dimension). As an alternative to making symmetry assumptions, one can study the stability of a given model. The question is then, given a model, say that we perturb the initial data slightly, is the spacetime that results by evolving the perturbed data similar? Interestingly enough, it turns out that even proving the non-linear stability of Minkowski space is a very difficult problem.