Abstract

0. Introduction. The main goal of this paper is to give a unified description for the structure of the small quantum cohomology rings for all projective homogeneous spaces SLn(C)/P , where P is a parabolic subgroup. The quantum cohomology ring of a smooth projective variety, or more generally of a symplectic manifoldX, has been introduced by string theorists (see [Va] and [W1]). Roughly speaking, it is a deformation of the usual cohomology ring, with parameter space given byH ∗(X). The multiplicative structure of quantum cohomology encodes the enumerative geometry of rational curves on X. In the past few years, the highly nontrivial task of giving a rigorous mathematical treatment of quantum cohomology has been accomplished both in the realm of algebraic and symplectic geometry. In various degrees of generality, this can be found in [Beh], [BehM], [KM], [LiT1], [LiT2], [McS], and [RT], as well as in the surveys [FP] and [T]. If one restricts the parameter space to H 1,1(X), one gets the small quantum cohomology ring. This ring, in the case of partial flag varieties, is the object of the present paper. In order to state our main results, we first describe briefly the “classical” side of the story. We interpret the homogeneous space F := SLn(C)/P as the complex, projective variety, parametrizing flags of quotients of C of given ranks, say, nk > · · ·> n1. By a classical result of Ehresmann [E], the integral cohomology of F can be described geometrically as the free abelian group generated by the Schubert classes. These are the (Poincare duals of) fundamental classes of certain subvarieties w ⊂ F , one for each element of the subset S := S(n1, . . . ,nk) of the symmetric group Sn, consisting of permutations w with descents in {n1, . . . ,nk}. A description of the multiplicative structure is provided by yet another classical theorem, due to Borel [Bor], which gives a presentation forH ∗(F,Z). Specifically, let σ 1 1 , . . . ,σ 1 n1 ,σ 2 1 , . . . ,σ 2 n2−n1, . . . ,σ k+1 1 , . . . ,σ k+1 n−nk be n independent variables. Define An to be the block-diagonal matrix diag(D1,D2, . . . ,Dk+1), where

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