Kazhdan–Lusztig polynomial

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In representation theory, a Kazhdan–Lusztig polynomial P_y,w(q) is a member of a family of integral polynomials introduced in work of David Kazhdan and George Lusztig (Kazhdan & Lusztig 1979). They are indexed by pairs of elements y, w of a Coxeter group W, which can in particular be the Weyl group of a Lie group.

Contents 1 Motivation and history 2 Definition 3 Examples 4 Kazhdan-Lusztig conjectures 4.1 Remarks 5 Generalization to real groups 6 Generalization to other objects in representation theory 7 Combinatorial theory 8 References 9 External links

[edit] Motivation and history

In the spring of 1978 Kazhdan and Lusztig were studying a representation of the Weyl group of an algebraic group on l-adic cohomology groups related to unipotent conjugacy classes, introduced shortly before by Springer. They found a new construction of this representation over the complex numbers (Kazhdan and Lusztig A topological approach to Springer's representation, Adv. Math. 38 (1980) 222-228). The representation had two natural bases, and the transition matrix between these two bases is essentially given by the Kazhdan–Lusztig polynomials. The actual Kazhdan-Lusztig construction of their polynomials is more elementary. Kazhdan and Lusztig used this to construct a canonical basis in the Hecke algebra of the Coxeter group and its representations.

In their first paper Kazhdan and Lusztig mentioned that their polynomials were related to the failure of local Poincaré duality for Schubert varieties. In (Kazhdan & Lusztig 1980) they reinterpreted this in terms of the intersection cohomology of Mark Goresky and Robert MacPherson, and gave another definition of such a basis in terms of the dimensions of certain intersection cohomology groups.

The two bases for the Springer representation reminded Kazhdan and Lusztig of the two bases for the Grothendieck group of certain infinite dimensional representations of semisimple Lie algebras, given by Verma modules and simple modules. This analogy, and the work of C. J. Jantzen and A. Joseph relating primitive ideals of enveloping algebras to representations of Weyl groups, led to the Kazhdan-Lusztig conjectures.

[edit] Definition

Fix a Coxeter group W with generating set S, and write l(w) for the length of an element w (the smallest length of an expression for w as a product of elements of S). The Hecke algebra of W has a basis of elements T_w for w∈W over the ring Z[q^1/2, q^−1/2], with multiplication defined by

T_yT_w = T_yw if l(yw) = l(y) + l(w)

(T_s + 1)(T_s − q) = 0 if s ∈ S.

The Kazhdan-Lusztig polynomials P_yw(q) are indexed by a pair of elements y, w of W, and uniquely determined by the following properties.

• They are 0 unless y ≤ w (in the Bruhat order of W), 1 if y = w, and for y < w their degree is at most (l(w) − l(y) − 1)/2.
• The elements

are invariant under the involution D of the Hecke algebra taking q^{1 / 2} to q ^{− 1 / 2} and T_w to for all elements w ∈ W.

To establish existence, Kazhdan and Lusztig gave a simple recursive procedure for computing the polynomials P_yw(q) in terms of more elementary polynomials denoted R_yw(q). defined by

They can be computed using the recursion relations

R_x,y = 1 if x=y and 0 unless x≤y,

R_x,y = R_sx,sy if sx<x and sy<y,

R_x,y = R_xs,ys if xs<x and ys<y,

R_x,y = (q − 1)R_sx,y + qR_sx,sy if sx>x and sy<y.

The Kazhdan-Lusztig polynomials can then be computed recursively using the relation

using the fact that the two terms on the left are polynomials in q^1/2 and q^−1/2 without constant terms. These formulas are tiresome to use by hand for rank greater than about 3, but are well adapted for computers, and the only limit on computing Kazhdan-Lusztig polynomials with them is that for large rank the number of such polynomials exceeds the storage capacity of computers.

[edit] Examples

• If y ≤ w then P_y,w has constant term 1.
• If y ≤ w and l(w) − l(y) is 0, 1, or 2 then P_y,w = 1.
• If w is the longest element of a finite Coxeter group then P_y,w = 1
• If W is the Coxeter group A₁ or A₂ (or more generally any Coxeter group of rank at most 2) then P_y,w is 1 if y≤w and 0 otherwise.
• If W is the Coxeter group A₃ with generating set S = {a, b, c} with a and c commuting then P_b,bacb = 1 + q and P_ac,acbca = 1 + q, giving examples of non-constant polynomials.
• The simple values of Kazhdan-Lusztig polynomials for low rank groups are not typical of higher rank groups. For example, for the split form of E₈ the most complicated Lusztig-Vogan polynomial (a variation of Kazhdan-Lusztig polynomials: see below) is

152q²² + 3,472q²¹ + 38,791q²⁰ + 293,021q¹⁹ + 1,370,892q¹⁸ + 4,067,059q¹⁷ + 7,964,012q¹⁶ + 11,159,003q¹⁵ + 11,808,808q¹⁴ + 9,859,915q¹³ + 6,778,956q¹² + 3,964,369q¹¹ + 2,015,441q¹⁰ + 906,567q⁹ + 363,611q⁸ + 129,820q⁷ + 41,239q⁶ + 11,426q⁵ + 2,677q⁴ + 492q³ + 61q² + 3q

In fact any polynomial with constant term 1 and non-negative integer coefficients is the Kazhdan-Lusztig polynomial for some pair of elements of some symmetric group.

[edit] Kazhdan-Lusztig conjectures

The Kazhdan-Lusztig polynomials arise as transition coefficients between their canonical basis and the natural basis of the Hecke algebra. The Inventiones paper also put forth two equivalent conjectures, known now as Kazhdan-Lusztig conjectures, which related the values of their polynomials at 1 with representations of complex semisimple Lie groups and Lie algebras, addressing a long-standing problem in representation theory.

Let W be a finite Weyl group. For each w∈W denote by M_w be the Verma module of highest weight −w(ρ)−ρ where ρ is the half-sum of positive roots (or Weyl vector), and let L_w be its irreducible quotient, the simple highest weight module of highest weight −w(ρ) − ρ. Both M_w and L_w are locally-finite weight modules over the complex semisimple Lie algebra g with the Weyl group W, and therefore admit an algebraic character. Let us write ch(X) for the character of a g-module X. The Kazhdan-Lusztig conjectures state:

where w₀ is the element of maximal length of the Weyl group.

These conjectures were proved independently by Alexander Beilinson and Joseph Bernstein (1981) and by Jean-Luc Brylinski and Masaki Kashiwara (1981). The methods introduced in the course of the proof have guided development of representation theory throughout the 1980s and 1990s, under the name geometric representation theory.

[edit] Remarks

1. The two conjectures are known to be equivalent. Moreover, Borho-Jantzen's translation principle implies that ρ can be replaced by any dominant regular integral weight. Thus, Kazhdan-Lusztig conjectures describe the Jordan-Hölder multiplicities of Verma modules in any regular integral block of Bernstein-Gelfand-Gelfand category O.

2. A similar interpretation of all coefficients of Kazhdan-Lusztig polynomials follows from the Jantzen conjecture, which roughly says that individual coefficients of P_y,w are multiplicities of L_y in certain subquotient of the Verma module determined by a canonical filtration, the Jantzen filtration. The Jantzen conjecture in regular integral case was proved in a later paper of Beilinson and Bernstein.

3. David Vogan showed as a consequence of the conjectures that

and that Ext^j(M_y,L_w) vanishes if j + l(w) + l(y) is odd, so the dimensions of all such Ext groups in category O are determined in terms of coefficients of Kazhdan-Lusztig polynomials. This result demonstrates that all coefficients of the Kazhdan-Lusztig polynomials of a finite Weyl group are non-negative integers. However, positivity for the case of a finite Weyl group W was already known from the interpretation of coefficients of the Kazhdan-Lusztig polynomials as the dimensions of intersection cohomology groups, irrespective of the conjectures. Conversely, the relation between Kazhdan-Lusztig polynomials and the Ext groups theoretically can be used to prove the conjectures, although this approach to proving them turned out to be more difficult to carry out.

4. Some special cases of the Kazhdan-Lusztig conjectures are easy to verify. For example, M₁ is the antidominant Verma module, which is known to be simple. This means that M₁ = L₁, establishing the second conjecture for w=1, since the sum reduces to a single term. On the other hand, the first conjecture for w = w₀ follows from the Weyl character formula and the formula for the character of a Verma module, together with the fact that all Kazhdan-Lusztig polynomials are equal to 1.

5. Kashiwara (1990) proved a generalization of the Kazhdan-Lusztig conjectures to symmetrizable Kac-Moody algebras.

[edit] Generalization to real groups

Lusztig-Vogan polynomials (also called Kazhdan-Lusztig polynomials or Kazhdan-Lusztig-Vogan polynomials) were introduced in Lusztig and Vogan (1983). They are analogous to Kazhdan-Lusztig polynomials, but are tailored to representations of real semisimple Lie groups, and play major role in the conjectural description of their unitary duals. Their definition is more complicated, reflecting relative complexity of representations of real groups compared to complex groups.

The distinction, in the cases directly connection to representation theory, is explained on the level of double cosets; or in other terms of actions on analogues of complex flag manifolds G/B where G is a complex Lie group and B a Borel subgroup. The original (K-L) case is then about the details of decomposing

B\G/B,

a classical theme of the Bruhat decomposition, and before that of Schubert cells in a Grassmannian. The L-V case takes a real form G_R of G, a maximal compact subgroup K_R in that semisimple group G_R, and makes the complexification K of K_R. Then the relevant object of study is

K\G/B.

[edit] Generalization to other objects in representation theory

The second paper of Kazhdan and Lusztig established a geometric setting for definition of Kazhdan-Lusztig polynomials, namely, the geometry of singularities of Schubert varieties in the flag variety. Much of the later work of Lusztig explored analogues of Kazhdan-Lusztig polynomials in the context of other natural singular algebraic varieties arising in representation theory, in particular, closures of nilpotent orbits and quiver varieties. It turned out that the representation theory of quantum groups, modular Lie algebras and affine Hecke algebras are all tightly controlled by appropriate analogues of Kazhdan-Lusztig polynomials. They admit an elementary description, but the deeper properties of these polynomials necessary for representation theory follow from sophisticated techniques of modern algebraic geometry and homological algebra, such as the use of intersection cohomology, perverse sheaves and Beilinson-Bernstein-Deligne decomposition.

[edit] Combinatorial theory

Combinatorial properties of Kazhdan-Lusztig polynomials and their generalizations are a topic of active current research. Given their significance in representation theory and algebraic geometry, attempts have been undertaken to develop the theory of Kazhdan-Lusztig polynomials in purely combinatorial fashion, relying to some extent on geometry, but without reference to intersection cohomology and other advanced techniques. This has led to exciting developments in algebraic combinatorics, such as pattern-avoidance phenomenon. Some references are given in the textbook of Bjorner and Brenti. A research monograph on the subject is Billey and Lakshmibai.

As of 2005, there is no known combinatorial interpretation of all the coefficients of the Kazhdan-Lusztig polynomials (as the cardinalities of some natural sets) even for the symmetric groups, though explicit formulas exist in many special cases.

[edit] References

• Beilinson, Alexandre; Bernstein, Joseph Localisation de g-modules. C. R. Acad. Sci. Paris Sér. I Math. 292 (1981), no. 1, 15--18.
• Billey, Sara & V. Lakshmibai (2000), Singular loci of Schubert varieties, vol. 182 of Progress in Mathematics, Birkhäuser Boston, Inc., Boston, MA, ISBN 0-8176-4092-4
• Björner, Anders & Francesco Brenti (2005), "Ch. 5: Kazhdan–Lusztig and R-polynomials", Combinatorics of Coxeter Groups, vol. 231 of Graduate Texts in Mathematics, Springer, ISBN 978-3-540-44238-7
• Brenti, Francesco (2003), "Kazhdan-Lusztig Polynomials: History, Problems, and Combinatorial Invariance", Séminaire Lotharingien de Combinatoire, B49b 49, Ellwangen: Haus Schönenberg
• Brylinski, Jean-Luc & Masaki Kashiwara (1981), "Kazhdan-Lusztig conjecture and holonomic systems", Inventiones Mathematicae 64 (3): 387-410, Springer-Verlag, DOI:10.1007/BF01389272
• M. Kashiwara, The Kazhdan-Lusztig conjecture for symmetrizable KacMoody algebras, in: The Grothendieck Festschrift, II, Birkhauser, Progress in Mathem. 87, Boston, 1990, pp. 407-433. MR93a:17026
• Kazhdan, David & George Lusztig (1979), "Representations of Coxeter groups and Hecke algebras", Inventiones Mathematicae 53 (2): 165–184, Springer-Verlag, DOI:10.1007/BF01390031
• Kazhdan, David & George Lusztig (1980), "Schubert varieties and Poincaré duality", Proc. Sympos. Pure Math., XXXVI: 185-203, American Mathematical Society
• Lusztig, George & David Vogan (1983), "Singularities of closures of K-orbits on flag manifolds.", Inventiones Mathematicae 71 (2): 365-379, Springer-Verlag, DOI:10.1007/BF01389103

[edit] External links

• Readings from Spring 2005 course on Kazhdan-Lusztig Theory at U.C. Davis by Monica Vazirani
• Goresky's tables of Kazhdan-Lusztig polynomials.
• The GAP programs for computing Kazhdan-Lusztig polynomials.
• Atlas software for computing Kazhdan-Lusztig polynomials.