Geodesic
The Generalized Cuspidal Cohomology Problem
Canadian journal of mathematics, Tome 58 (2006) no. 4, pp. 673-690

Voir la notice de l'article provenant de la source Cambridge University Press

Let $\Gamma \subset SO(3,1)$ be a lattice. The well known bending deformations, introduced by Thurston and Apanasov, can be used to construct non-trivial curves of representations of $\Gamma $ into $SO(4,1)$ when $\Gamma \backslash {{\mathbb{H}}^{3}}$ contains an embedded totally geodesic surface. A tangent vector to such a curve is given by a non-zero group cohomology class in ${{\text{H}}^{1}}\left( \Gamma ,\mathbb{R}_{1}^{4} \right)$ . Our main result generalizes this construction of cohomology to the context of “branched” totally geodesic surfaces. We also consider a natural generalization of the famous cuspidal cohomology problem for the Bianchi groups (to coefficients in non-trivial representations), and perform calculations in a finite range. These calculations lead directly to an interesting example of a link complement in ${{S}^{3}}$ which is not infinitesimally rigid in $SO(4,1)$ . The first order deformations of this link complement are supported on a piecewise totally geodesic 2-complex.
DOI : 10.4153/CJM-2006-028-1
Mots-clés : 57M50, 22E40 
Bart, Anneke; Scannell, Kevin P. The Generalized Cuspidal Cohomology Problem. Canadian journal of mathematics, Tome 58 (2006) no. 4, pp. 673-690. doi: 10.4153/CJM-2006-028-1
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