English

Archimedean superrigidity of solvable S-arithmetic groups

Representation Theory 2016-09-06 v1 Number Theory

Abstract

Let \Ga\Ga be a connected, solvable linear algebraic group over a number field~KK, let SS be a finite set of places of~KK that contains all the infinite places, and let \theints\theints be the ring of SS-integers of~KK. We define a certain closed subgroup~\GOS\GOS of \GaS=vS\GaKv\Ga_S = \prod_{v \in S} \Ga_{K_v} that contains \Ga\theints\Ga_{\theints}, and prove that \Ga\theints\Ga_{\theints} is a superrigid lattice in~\GOS\GOS, by which we mean that finite-dimensional representations α ⁣:\Ga\theints\GLn()\alpha\colon \Ga_{\theints} \to \GL_n(\real) more-or-less extend to representations of~\GOS\GOS. The subgroup~\GOS\GOS may be a proper subgroup of~\GaS\Ga_S for only two reasons. First, it is well known that \Ga\theints\Ga_{\theints} is not a lattice in~\GaS\Ga_S if \Ga\Ga has nontrivial KK-characters, so one passes to a certain subgroup \GS\GS. Second, \Ga\theints\Ga_{\theints} may fail to be Zariski dense in \GS\GS in an appropriate sense; in this sense, the subgroup \GOS\GOS is the Zariski closure of~\Ga\theints\Ga_{\theints} in~\GS\GS. Furthermore, we note that a superrigidity theorem for many non-solvable SS-arithmetic groups can be proved by combining our main theorem with the Margulis Superrigidity Theorem.

Keywords

Cite

@article{arxiv.math/9611219,
  title  = {Archimedean superrigidity of solvable S-arithmetic groups},
  author = {Dave Witte},
  journal= {arXiv preprint arXiv:math/9611219},
  year   = {2016}
}