Journal of Algebraic Combinatorics (EMIS Electronic Version)

Home > Vol 36, No 4 (2012)

Affine Stanley symmetric functions for classical types

Steven Pon

University of Connecticut, Storrs, CT, 06269, USA

DOI: 10.1007/s10801-012-0352-6

Abstract

We introduce affine Stanley symmetric functions for the special orthogonal groups, a class of symmetric functions that model the cohomology of the affine Grassmannian, continuing the work of Lam and Lam, Schilling, and Shimozono on the special linear and symplectic groups, respectively. For the odd orthogonal groups, a Hopf-algebra isomorphism is given, identifying (co)homology Schubert classes with symmetric functions. For the even orthogonal groups, we conjecture an approximate model of (co)homology via symmetric functions. In the process, we develop type B and type D non-commutative k-Schur functions as elements of the affine nilCoxeter algebra that model homology of the affine Grassmannian. Additionally, Pieri rules for multiplication by special Schubert classes in homology are given in both cases. Finally, we present a type-free interpretation of Pieri factors, used in the definition of noncommutative k-Schur functions or affine Stanley symmetric functions for any classical type.

Pages: 595–622

Keywords: affine Schubert calculus; Stanley symmetric functions; Pieri factors

Full Text: PDF

References

Billey, S., Haiman, M.: Schubert polynomials for the classical groups. J. Am. Math. Soc. 8, 443-482 (1994) CrossRef Billey, S., Jockusch, W., Stanley, R.: Some combinatorial properties of Schubert polynomials. J. Algebr. Comb. 2, 345-374 (1993) CrossRef Billey, S., Mitchell, S.: Affine partitions and affine Grassmannians. Electron. J. Comb. $16(2) (2009)$ Björner, A., Brenti, F.: Combinatorics of Coxeter Groups. Springer, Berlin (2005) Bott, R.: The space of loops on a Lie group. Mich. Math. J. $5(1)$, 35-61 (1958) CrossRef Carter, R.: Lie Algebras of Finite and Affine Type. Cambridge University Press, Cambridge (2005) CrossRef Eriksson, H., Eriksson, K.: Affine Weyl groups as infinite permutations. Electron. J. Comb. 5, 1-8 (1998) Fomin, S., Kirillov, A.: Combinatorial Bn-analogues of Schubert polynomials. Trans. Am. Math. Soc. 348, 3591-3620 (1996) CrossRef Fomin, S., Stanley, R.: Schubert polynomials and the nilCoxeter algebra. Adv. Math. 103, 196-207 (1994) CrossRef Fourier, G., Littelmann, P.: Weyl modules, Demazure modules, KR-modules, crystals, fusion products and limit constructions. Adv. Math. 211, 566-593 (2007) CrossRef Graham, W.: Positivity in equivariant Schubert calculus. Duke Math. J. 109, 599-614 (2001) CrossRef Humphreys, J.: Reflection Groups and Coxeter Groups. Cambridge University Press, Cambridge (1990) CrossRef Kac, V.: Infinite-Dimensional Lie Algebras. Cambridge University Press, Cambridge (1990) CrossRef Kumar, S.: Kac-Moody Groups, Their Flag Varieties and Representation Theory. Birkhäuser, Boston (2002) CrossRef Lam, T.: Affine Stanley symmetric functions. Am. J. Math. 128, 1553-1586 (2006) CrossRef Lam, T.: Schubert polynomials for the affine Grassmannian. J. Am. Math. Soc. 21, 259-281 (2008) CrossRef Lam, T.: Affine Schubert classes, Schur positivity, and combinatorial Hopf algebras. Bull. Lond. Math. Soc. $43(2)$, 328-334 (2011) CrossRef Lam, T., Schilling, A., Shimozono, M.: Schubert polynomials for the affine Grassmannian of the symplectic group. Math. Z. 264, 765-811 (2010) CrossRef Lam, T., Shimzono, M.: Quantum cohomology of G/P and homology of affine Grassmannian. Acta Math. 204, 49-90 (2010) CrossRef Lam, T.K.: B and D analogues of stable Schubert polynomials and related insertion algorithms. Ph.D. thesis, Massachusetts Institute of Technology (1995) Lam, T.K.: Bn Stanley symmetric functions. Discrete Math. 157, 241-270 (1996) CrossRef Lapointe, L., Lascoux, A., Morse, J.: Tableau atoms and a new Macdonald positivity conjecture. Duke Math. J. 116, 103-146 (2003) CrossRef Lascoux, A., Pragacz, P.: Orthogonal divided differences and Schubert polynomials, $\tilde{P}$ -functions, and vertex operators. Mich. Math. J. 48, 417-441 (2000) CrossRef Lascoux, A., Schutzenberger, M.: Polynomes de Schubert. C. R. Acad. Sci., Ser. 1 Math. 294, 447-450 (1982) Macdonald, I.: Notes on Schubert Polynomials. Publications du Laboratoire de Combinatoire et d' Informatique Mathematique, vol. 6 (1991) Macdonald, I.: Symmetric Functions and Hall Polynomials, 2nd edn. Oxford University Press, London (1995) Mitchell, S.: Quillen's theorem on buildings and the loops on a symmetric space. Enseign. Math. 34, 123-166 (1988) Peterson, D.: Quantum Cohomology of G/P. Lecture Notes at MIT (1997) Pittman-Polletta, B.: Factorization in loop groups. Ph.D. thesis, University of Arizona (2010) Pon, S.: Affine Stanley symmetric functions for classical groups. Ph.D. thesis, University of California, Davis (2010) Pragacz, P., Ratajski, J.: Formulas of Lagrangian and orthogonal degeneracy loci; $\tilde{Q}$ -polynomial approach. Compos. Math. 107, 11-87 (1997) CrossRef Pressley, A., Segal, G.: Loop Groups. Oxford Science Publications, Oxford (1986) Sage-Combinat Community: Sage-Combinat: enhancing sage as a toolbox for computer exploration in algebraic combinatorics. http://combinat.sagemath.org (2008) Stanley, R.: On the number of reduced decompositions of elements of Coxeter groups. Eur. J. Comb. 5, 359-372 (1984) Stein, W., et al.: Sage Mathematics Software (Version 4.5.2). The Sage Development Team (2010). http://www.sagemath.org Stembridge, J.: Shifted tableaux and the projective representations of symmetric groups. In: Adv. Math. 87-134 (1989)

	EMIS Electronic Library of Mathematics (ELibM) The Open Access Repository of Mathematics
	JOURNAL OF ALGEBRAIC COMBINATORICS
	Editors-in-chief: C. A. Athanasiadis, T. Lam, A. Munemasa, H. Van Maldeghem ISSN 0925-9899 (print) • ISSN 1572-9192 (electronic)
	Home > Vol 36, No 4 (2012) Affine Stanley symmetric functions for classical types Steven Pon University of Connecticut, Storrs, CT, 06269, USA DOI: 10.1007/s10801-012-0352-6 Abstract We introduce affine Stanley symmetric functions for the special orthogonal groups, a class of symmetric functions that model the cohomology of the affine Grassmannian, continuing the work of Lam and Lam, Schilling, and Shimozono on the special linear and symplectic groups, respectively. For the odd orthogonal groups, a Hopf-algebra isomorphism is given, identifying (co)homology Schubert classes with symmetric functions. For the even orthogonal groups, we conjecture an approximate model of (co)homology via symmetric functions. In the process, we develop type B and type D non-commutative k-Schur functions as elements of the affine nilCoxeter algebra that model homology of the affine Grassmannian. Additionally, Pieri rules for multiplication by special Schubert classes in homology are given in both cases. Finally, we present a type-free interpretation of Pieri factors, used in the definition of noncommutative k-Schur functions or affine Stanley symmetric functions for any classical type. Pages: 595–622 Keywords: affine Schubert calculus; Stanley symmetric functions; Pieri factors Full Text: PDF References Billey, S., Haiman, M.: Schubert polynomials for the classical groups. J. Am. Math. Soc. 8, 443-482 (1994) CrossRef Billey, S., Jockusch, W., Stanley, R.: Some combinatorial properties of Schubert polynomials. J. Algebr. Comb. 2, 345-374 (1993) CrossRef Billey, S., Mitchell, S.: Affine partitions and affine Grassmannians. Electron. J. Comb. $16(2) (2009)$ Björner, A., Brenti, F.: Combinatorics of Coxeter Groups. Springer, Berlin (2005) Bott, R.: The space of loops on a Lie group. Mich. Math. J. $5(1)$, 35-61 (1958) CrossRef Carter, R.: Lie Algebras of Finite and Affine Type. Cambridge University Press, Cambridge (2005) CrossRef Eriksson, H., Eriksson, K.: Affine Weyl groups as infinite permutations. Electron. J. Comb. 5, 1-8 (1998) Fomin, S., Kirillov, A.: Combinatorial Bn-analogues of Schubert polynomials. Trans. Am. Math. Soc. 348, 3591-3620 (1996) CrossRef Fomin, S., Stanley, R.: Schubert polynomials and the nilCoxeter algebra. Adv. Math. 103, 196-207 (1994) CrossRef Fourier, G., Littelmann, P.: Weyl modules, Demazure modules, KR-modules, crystals, fusion products and limit constructions. Adv. Math. 211, 566-593 (2007) CrossRef Graham, W.: Positivity in equivariant Schubert calculus. Duke Math. J. 109, 599-614 (2001) CrossRef Humphreys, J.: Reflection Groups and Coxeter Groups. Cambridge University Press, Cambridge (1990) CrossRef Kac, V.: Infinite-Dimensional Lie Algebras. Cambridge University Press, Cambridge (1990) CrossRef Kumar, S.: Kac-Moody Groups, Their Flag Varieties and Representation Theory. Birkhäuser, Boston (2002) CrossRef Lam, T.: Affine Stanley symmetric functions. Am. J. Math. 128, 1553-1586 (2006) CrossRef Lam, T.: Schubert polynomials for the affine Grassmannian. J. Am. Math. Soc. 21, 259-281 (2008) CrossRef Lam, T.: Affine Schubert classes, Schur positivity, and combinatorial Hopf algebras. Bull. Lond. Math. Soc. $43(2)$, 328-334 (2011) CrossRef Lam, T., Schilling, A., Shimozono, M.: Schubert polynomials for the affine Grassmannian of the symplectic group. Math. Z. 264, 765-811 (2010) CrossRef Lam, T., Shimzono, M.: Quantum cohomology of G/P and homology of affine Grassmannian. Acta Math. 204, 49-90 (2010) CrossRef Lam, T.K.: B and D analogues of stable Schubert polynomials and related insertion algorithms. Ph.D. thesis, Massachusetts Institute of Technology (1995) Lam, T.K.: Bn Stanley symmetric functions. Discrete Math. 157, 241-270 (1996) CrossRef Lapointe, L., Lascoux, A., Morse, J.: Tableau atoms and a new Macdonald positivity conjecture. Duke Math. J. 116, 103-146 (2003) CrossRef Lascoux, A., Pragacz, P.: Orthogonal divided differences and Schubert polynomials, $\tilde{P}$ -functions, and vertex operators. Mich. Math. J. 48, 417-441 (2000) CrossRef Lascoux, A., Schutzenberger, M.: Polynomes de Schubert. C. R. Acad. Sci., Ser. 1 Math. 294, 447-450 (1982) Macdonald, I.: Notes on Schubert Polynomials. Publications du Laboratoire de Combinatoire et d' Informatique Mathematique, vol. 6 (1991) Macdonald, I.: Symmetric Functions and Hall Polynomials, 2nd edn. Oxford University Press, London (1995) Mitchell, S.: Quillen's theorem on buildings and the loops on a symmetric space. Enseign. Math. 34, 123-166 (1988) Peterson, D.: Quantum Cohomology of G/P. Lecture Notes at MIT (1997) Pittman-Polletta, B.: Factorization in loop groups. Ph.D. thesis, University of Arizona (2010) Pon, S.: Affine Stanley symmetric functions for classical groups. Ph.D. thesis, University of California, Davis (2010) Pragacz, P., Ratajski, J.: Formulas of Lagrangian and orthogonal degeneracy loci; $\tilde{Q}$ -polynomial approach. Compos. Math. 107, 11-87 (1997) CrossRef Pressley, A., Segal, G.: Loop Groups. Oxford Science Publications, Oxford (1986) Sage-Combinat Community: Sage-Combinat: enhancing sage as a toolbox for computer exploration in algebraic combinatorics. http://combinat.sagemath.org (2008) Stanley, R.: On the number of reduced decompositions of elements of Coxeter groups. Eur. J. Comb. 5, 359-372 (1984) Stein, W., et al.: Sage Mathematics Software (Version 4.5.2). The Sage Development Team (2010). http://www.sagemath.org Stembridge, J.: Shifted tableaux and the projective representations of symmetric groups. In: Adv. Math. 87-134 (1989) © 1992–2009 Journal of Algebraic Combinatorics © 2012 FIZ Karlsruhe / Zentralblatt MATH for the EMIS Electronic Edition

JOURNAL OF ALGEBRAIC COMBINATORICS

Affine Stanley symmetric functions for classical types

Abstract

References

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