Schubert polynomial

In mathematics, Schubert polynomials are generalizations of Schur polynomials that represent cohomology classes of Schubert cycles in flag varieties. They were introduced by Lascoux & Schützenberger (1982) and are named after Hermann Schubert.

Background

Lascoux (1995) described the history of Schubert polynomials.

The Schubert polynomials \mathfrak{S}_w are polynomials in the variables \  x_1,x_2,\ldots depending on an element w of the infinite symmetric group S_\infty of all permutations of 1, 2, 3,\ldots fixing all but a finite number of elements. They form a basis for the polynomial ring  \mathbb{Z}[x_1,x_2,\ldots] in infinitely many variables.

The cohomology of the flag manifold  \text{Fl}(m) is \mathbb{Z}[x_1,x_2,\ldots,x_m]/I, where I is the ideal generated by homogeneous symmetric functions of positive degree. The Schubert polynomial \mathfrak{S}_w is the unique homogeneous polynomial of degree  \ell(w) representing the Schubert cycle of  w in the cohomology of the flag manifold  \text{Fl}(m) for all sufficiently large  m.

Properties

Schubert polynomials can be calculated recursively from these two properties. In particular, this implies that  \mathfrak{S}_w = \partial_{w^{-1}w_0} x_1^{n-1}x_2^{n-2} \cdots x_{n-1}^1.

Other properties are


As an example \mathfrak{S}_{24531}(x) = x_1 x_3^2 x_4 x_2^2+x_1^2 x_3 x_4 x_2^2+x_1^2 x_3^2 x_4 x_2.

Multiplicative structure constants

Since the Schubert polynomials form a basis, there are unique coefficients c^{\alpha}_{\beta\gamma} such that \mathfrak{S}_\beta \mathfrak{S}_\gamma = \sum_\alpha c^{\alpha}_{\beta\gamma} \mathfrak{S}_\alpha. These can be seen as a generalization of the Littlewood−Richardson coefficients described by the Littlewood–Richardson rule. For representation-theoretical reasons, these coefficients are non-negative integers and it is an outstanding problem in representation theory and combinatorics to give a combinatorial rule for these numbers.

Double Schubert polynomials

Double Schubert polynomials \mathfrak{S}_w(x_1,x_2,\ldots, y_1,y_2,\ldots) are polynomials in two infinite sets of variables, parameterized by an element w of the infinite symmetric group, that becomes the usual Schubert polynomials when all the variables y_i are 0.

The double Schubert polynomial \mathfrak{S}_w(x_1,x_2,\ldots, y_1,y_2,\ldots) are characterized by the properties


The double Schubert polynomials can also be defined as \mathfrak{S}_w(x,y) =\sum_{   w=v^{-1}u \text{ and } \ell(w)=\ell(u)+\ell(v) } \mathfrak{S}_u(x)  \mathfrak{S}_v(-y).

Quantum Schubert polynomials

Fomin, Gelfand & Postnikov (1997) introduced quantum Schubert polynomials, that have the same relation to the (small) quantum cohomology of flag manifolds that ordinary Schubert polynomials have to the ordinary cohomology.

Universal Schubert polynomials

Fulton (1999) introduced universal Schubert polynomials, that generalize classical and quantum Schubert polynomials. He also described universal double Schubert polynomials generalizing double Schubert polynomials.

See also

References

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