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Affine Grassmannian

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For the variety of all k-dimensional affine subspaces of a finite-dimensional vector space (a smooth finite-dimensional variety over k), see affine Grassmannian (manifold).

In mathematics, the affine Grassmannian of an algebraic group G over a field k is an ind-scheme—a colimit of finite-dimensional schemes—which can be thought of as a flag variety for the loop group G(k((t))) and which describes the representation theory of the Langlands dual group G through what is known as the geometric Satake correspondence.

Definition of Gr via functor of points

Let k be a field, and denote by k -Alg {\displaystyle k{\text{-Alg}}} and S e t {\displaystyle \mathrm {Set} } the category of commutative k-algebras and the category of sets respectively. Through the Yoneda lemma, a scheme X over a field k is determined by its functor of points, which is the functor X : k -Alg S e t {\displaystyle X:k{\text{-Alg}}\to \mathrm {Set} } which takes A to the set X(A) of A-points of X. We then say that this functor is representable by the scheme X. The affine Grassmannian is a functor from k-algebras to sets which is not itself representable, but which has a filtration by representable functors. As such, although it is not a scheme, it may be thought of as a union of schemes, and this is enough to profitably apply geometric methods to study it.

Let G be an algebraic group over k. The affine Grassmannian GrG is the functor that associates to a k-algebra A the set of isomorphism classes of pairs (E, φ), where E is a principal homogeneous space for G over Spec A] and φ is an isomorphism, defined over Spec A((t)), of E with the trivial G-bundle G × Spec A((t)). By the Beauville–Laszlo theorem, it is also possible to specify this data by fixing an algebraic curve X over k, a k-point x on X, and taking E to be a G-bundle on XA and φ a trivialization on (X − x)A. When G is a reductive group, GrG is in fact ind-projective, i.e., an inductive limit of projective schemes.

Definition as a coset space

Let us denote by K = k ( ( t ) ) {\displaystyle {\mathcal {K}}=k((t))} the field of formal Laurent series over k, and by O = k [ [ t ] ] {\displaystyle {\mathcal {O}}=k]} the ring of formal power series over k. By choosing a trivialization of E over all of Spec O {\displaystyle \operatorname {Spec} {\mathcal {O}}} , the set of k-points of GrG is identified with the coset space G ( K ) / G ( O ) {\displaystyle G({\mathcal {K}})/G({\mathcal {O}})} .

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