In algebraic geometry, the Bott–Samelson resolution of a Schubert variety is a resolution of singularities. It was introduced by Bott & Samelson (1958) in the context of compact Lie groups.[1] The algebraic formulation is independently due to Hansen (1973) and Demazure (1974).
Definition
Let G be a connected reductive complex algebraic group, B a Borel subgroup and T a maximal torus contained in B.
Let Any such w can be written as a product of reflections by simple roots. Fix minimal such an expression:
so that . (ℓ is the length of w.) Let be the subgroup generated by B and a representative of . Let be the quotient:
with respect to the action of by
It is a smooth projective variety. Writing for the Schubert variety for w, the multiplication map
is a resolution of singularities called the Bott–Samelson resolution. has the property: and In other words, has rational singularities.[2]
There are also some other constructions; see, for example, Vakil (2006).
Notes
- ↑ Gorodski & Thorbergsson (2002).
- ↑ Brion (2005, Theorem 2.2.3.)
References
- Bott, Raoul; Samelson, Hans (1958), "Applications of the theory of Morse to symmetric spaces", American Journal of Mathematics, 80: 964–1029, doi:10.2307/2372843, MR 0105694.
- Brion, Michel (2005), "Lectures on the geometry of flag varieties", Topics in cohomological studies of algebraic varieties, Trends Math., Birkhäuser, Basel, pp. 33–85, arXiv:math/0410240, doi:10.1007/3-7643-7342-3_2, MR 2143072.
- Demazure, Michel (1974), "Désingularisation des variétés de Schubert généralisées", Annales Scientifiques de l'École Normale Supérieure (in French), 7: 53–88, MR 0354697.
- Gorodski, Claudio; Thorbergsson, Gudlaugur (2002), "Cycles of Bott-Samelson type for taut representations", Annals of Global Analysis and Geometry, 21 (3): 287–302, arXiv:math/0101209, doi:10.1023/A:1014911422026, MR 1896478.
- Hansen, H. C. (1973), "On cycles in flag manifolds", Mathematica Scandinavica, 33: 269–274 (1974), doi:10.7146/math.scand.a-11489, MR 0376703.
- Vakil, Ravi (2006), "A geometric Littlewood-Richardson rule", Annals of Mathematics, Second Series, 164 (2): 371–421, arXiv:math.AG/0302294, doi:10.4007/annals.2006.164.371, MR 2247964.