In mathematics, the Bruhat order (also called the strong order, strong Bruhat order, Chevalley order, Bruhat–Chevalley order, or Chevalley–Bruhat order) is a partial order on the elements of a Coxeter group, that corresponds to the inclusion order on Schubert varieties.
The Bruhat order on the Schubert varieties of a flag manifold or a Grassmannian was first studied by, and the analogue for more general semisimple algebraic groups was studied by . started the combinatorial study of the Bruhat order on the Weyl group, and introduced the name "Bruhat order" because of the relation to the Bruhat decomposition introduced by François Bruhat.
The left and right weak Bruhat orderings were studied by .
If is a Coxeter system with generators, then the Bruhat order is a partial order on the group . The definition of Bruhat order relies on several other definitions: first, reduced word for an element of is a minimum-length expression of as a product of elements of, and the length of is the length of its reduced words. Then the (strong) Bruhat order is defined by if some substring of some (or every) reduced word for is a reduced word for . (Here a substring is not necessarily a consecutive substring.)
There are two other related partial orders:
For more on the weak orders, see the article Weak order of permutations.
The Bruhat graph is a directed graph related to the (strong) Bruhat order. The vertex set is the set of elements of the Coxeter group and the edge set consists of directed edges whenever for some reflection and . One may view the graph as an edge-labeled directed graph with edge labels coming from the set of reflections. (One could also define the Bruhat graph using multiplication on the right; as graphs, the resulting objects are isomorphic, but the edge labelings are different.)
The strong Bruhat order on the symmetric group (permutations) has Möbius function given by
\mu(\pi,\sigma)=(-1)\ell(\sigma)-\ell(\pi)