Is there any purely algebraic proof of Borel-Weil-Bott theorem. I mean only techniques from Algebraic group. In each and every proof I have seen so far they use Lie group techniques and then translate to Algebraic group version. I need a proper reference which is easily readable.
Thanks in advance.
The simplest proof of Borel-Weil-Bott that I know is due to Demazure: he has two papers in Inventiones (one in 1968 the other in 1976) on the theorem, and the second is two pages long -- it gives a simplification of his previous proof, and he uses only algebro-geometric techniques. Both papers are readable.
Near the bottom of Jacob Lurie's homepage, you can find an exposition of the Borel-Weil-Bott theorem from an algebro-geometric standpoint. It is "easily readable" if you're familiar with the things like line bundles on projective varieties, semisimple algebraic groups, etc..
See J.C. Jantzen "Representations of Algebraic Groups" II.5 especially II.5.5.
There you will find an algebraic proof of the result in char. 0 (probably more-or-less Demazure's proof, mentioned in another answer). And you'll find a proof of some of what remains true in positive char (due to Henning Anderson).
$p>0$ remain to a large extent open and are natural follow-ups. As George indicates, Jantzen's book provides access to such questions in a unified framework. Andersen got started on his own work partly by exploring how Demazure's set-up might be adapted to characteristic $p$. But a full analogue of Bott's theorem probably requires some creative use of Kazhdan-Lusztig theory for the affine Weyl group.
$\endgroup$
Commented
Mar 22, 2010 at 20:26