English

1+1 wave maps into symmetric spaces

Differential Geometry 2007-05-23 v1 Analysis of PDEs Exactly Solvable and Integrable Systems

Abstract

We explain how to apply techniques from integrable systems to construct 2k2k-soliton homoclinic wave maps from the periodic Minkowski space S1×R1S^1\times R^1 to a compact Lie group, and more generally to a compact symmetric space. We give a correspondence between solutions of the -1 flow equation associated to a compact Lie group GG and wave maps into GG. We use B\"acklund transformations to construct explicit 2k2k-soliton breather solutions for the -1 flow equation and show that the corresponding wave maps are periodic and homoclinic. The compact symmetric space G/KG/K can be embedded as a totally geodesic submanifold of GG via the Cartan embedding. We prescribe the constraint condition for the -1 flow equation associated to GG which insures that the corresponding wave map into GG actually lies in G/KG/K. For example, when G/K=SU(2)/SO(2)=S2G/K=SU(2)/SO(2)=S^2, the constrained -1-flow equation associated to SU(2) has the sine-Gordon equation (SGE) as a subequation and classical breather solutions of the SGE are 2-soliton breathers. Thus our result generalizes the result of Shatah and Strauss that a classical breather solution of the SGE gives rise to a periodic homoclinic wave map to S2S^2. When the group GG is non-compact, the bi-invariant metric on GG is pseudo-Riemannian and B\"acklund transformations of a smooth solution often are singular. We use B\"acklund transformations to show that there exist smooth initial data with constant boundary conditions and finite energy such that the Cauchy problem for wave maps from R1,1R^{1,1} to the pseudo-Riemannian manifold SL(2,R)SL(2,R) develops singularities in finite time.

Keywords

Cite

@article{arxiv.math/0311074,
  title  = {1+1 wave maps into symmetric spaces},
  author = {Chuu-Lian Terng and Karen Uhlenbeck},
  journal= {arXiv preprint arXiv:math/0311074},
  year   = {2007}
}

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32 pages