On the unitary dual of classical and exceptional real split groups. Alessandra Pantano, University of California, Irvine MIT, March, 2010

On the unitary dual of classical and exceptional real split groups. Alessandra Pantano, University of California, Irvine MIT, March, 2010 1

PLAN OF THE TALK unitarizability of Langlands quotients for real split groups petite K-types? unitarizability of Langlands quotients for Hecke algebras Part 1. Spherical unitary dual of affine graded Hecke algebras Part 2. Unitary dual of real split groups Part 3. Petite K-types Part 4. Embedding of unitary duals 2

PART 1 Spherical unitary dual of affine graded Hecke algebras 3

Affine graded Hecke algebras (X,, ˇX, ˇ ) : root datum, with simple roots Π and Weyl group W h := X Z C and A := Sym(h). The affine graded Hecke algebra for is H := C[W] A. generators: {t sα : α Π} {ω: ω h} relations: t 2 s α = 1; ωt sα = t sα s α (ω) + ω, ˇα α Π, ω h Example: type A1. C[W] = C1 + Ct sα (t 2 s α = 1), A = Sym(Cα) αt sα = t sα α + 2. Elements of H := C[W] A are of the form: p(α) + q(α)t sα. 4

Spherical Unitary H-modules The Hecke algebra H := C[W] A has a -operation. Let V be an H-module. V is spherical if it contains the trivial representation of W. V is Hermitian if it has a non-degenerate invariant Hermitian form: x v 1, v 2 + v 1, x v 2 = 0 x H, v 1, v 2 V. V is unitary if, is positive definite. 5

Spherical Langlands quotients of H ν ȟ h : real and dominant C ν : the corresponding character of A = Sym(h) Spherical Principal Series X(ν) := H A C ν X(ν) is spherical, dimhom W (triv, X(ν)) = 1. (H acts on the left) Langlands Quotient L(ν) := unique irreducible quotient of X(ν) Every irreducible spherical H-module (with real central character) is isomorphic to L(ν) for some ν dominant. 6

An Hermitian form on L(ν) w 0 : longest Weyl group element L(ν) is Hermitian if and only if w 0 ν = ν. In this case, Barbasch and Moy define a (normalized) intertwining operator such that A(w 0, ν) has no poles A(w 0, ν): X(ν) X(w 0 ν) The image of A(w 0, ν) is L(ν), hence L(ν) X(ν) Ker(A(w 0,ν)) A(w 0, ν) gives a non-deg. invariant Hermitian form on L(ν). ψ Ŵ, we find an operator A ψ (w 0, ν) on V ψ. (A triv(w 0, ν) = 1.) 7

The operator A ψ (w 0, ν) on the W-type ψ A ψ (w 0, ν) decomposes a product of operators corresponding to simple reflections. If w 0 = s α1 s α2 s αn is a reduced decomposition of w 0 in W, then A ψ (w 0, ν) = n i=1 with ν i = s αn+1 i s αn 1 s αn ν. Each factor acts on Vψ, and has the form A ψ (s αi, ν i 1 ) A ψ (s α, γ) := Id+ α,γ ψ(s α) 1+ α,γ. (+1)-eigensp. of ψ(sα) 1 (+1)-eigensp. of ψ(sα) ( 1)-eigensp. of ψ(sα) 1 γ, α 1 + γ, α ( 1)-eigensp. of ψ(sα) 8

Untarity of a spherical Langlands Quotient L(ν) is unitary A ψ (w 0, ν) is positive semi-definite, ψ Ŵ Barbasch and Ciubotaru found a small subset of Ŵ which is sufficient to detect unitarity. These are the relevant W-types. A n 1 Bn, Cn Dn {(n m, m): 0 m [n/2]} {(n m, m) (0): 0 m [n/2]} {(n m) (m): 0 m n} {(n m, m) (0): 0 m [n/2]} {(n m) (m): 0 m [n/2]} G 2 {1 1, 2 1, 2 2 } F 4 {1 1, 4 2, 2 3, 8 1, 9 1 } E 6 {1p, 6p, 20p, 30p, 15q } E 7 {1a, 7 a, 27 a, 56 a, 21 b, 35 b, 105 b } E 8 {1x, 8z, 35x, 50x, 84x, 112z, 400z, 300x, 210x} 9

Spherical Unitary dual of a Hecke algebra of type A1 In type A1, there are two W-types (triv and sgn). L(ν) is unitary if and only if A ψ (w 0, ν) is positive semidefinite for ψ = triv and sgn. Because w 0 has length one, the intertwining operator has a single factor: A ψ (w 0, ν) = A ψ (s α, ν) := Id+ α,ν ψ(s α) 1+ α,ν. ψ ψ(s α ) A ψ (w 0, ν) triv 1 1 sgn 1 1 ν 1+ν L(ν) is unitary for 0 ν 1. H(A1)... 0 1 2 3 4 5 6 7 χ 10

Spherical Unitary dual of a Hecke algebra of type B2 Here w 0 = s e1 e 2 s e2 s e1 e 2 s e2. For ν = (a, b), A ψ (w 0, ν) factors as: A ψ (s e1 e 2, ( b, a))a ψ (s e2, ( b, a))a ψ (s e1 e 2, (a, b))a ψ (s e2, (a, b)) The factors are computed using the formula: A ψ (s α, γ) = Id+ α,γ ψ(s α) 1+ α,γ. ψ Ŵ rel ψ(s e1 e 2 ) ψ(s e2 ) the operator A ψ (w 0, ν) 2 0 1 1 1 1 1 1 11 0 1 1 1 (a b) 1+(a b) 1 1 (a+b) 1+(a+b) 1 0 2 1 1 1 1 a 1+a 1 1 b 1+b ( ) ( ) 1+a tr. 2 2 a 3 b b 2 +ab+ab 3 1 1 0 1 1 0 1 0 0 1 det (1+a)(1+b)[1+(a b)][1+(a+b)] 1 b 1 (a b) 1 (a+b) 1+b 1+(a b) 1+(a+b) 1 a 1+a 11

Spherical unitary dual of a Hecke algebra of type B2 a = b H(B2) 0 1 2 a = 0 12

The spherical unitary dual of a Hecke algebra H: affine graded Hecke algebra with root system g: complex Lie algebra associated to The spherical unitary dual of H is a union of sets (complementary series) parameterized by nilpotent orbits in g. Fix an orbit O and its Lie triple {e, h, f}. The centralizer in g of the Lie triple is a reductive Lie subalgebra, denoted Z g (O). The complementary series attached to O, denoted by CS(O), is the set of all parameters ν such that L(ν) is unitary O is the maximal nilpotent orbit with the property ν = 1 2 h + χ, with χ Z g(o). 13

Complementary series attached to nilpotent orbits Fix a Hecke algebra H and an orbit O. Barbasch and Ciubotaru reduce the problem of finding the complementary series CS(O) of H to the problem of detecting the zero-complementary series CS(0) of the centralizer of O. With a few exceptions (one orbit for F4 and E 7, and 6 orbits for E8), they prove that ν = 1 2 h + χ CS H(O) χ CS H(Z(O)) (0). The zero-complementary series CS(0) = {ν : X(ν) is unitary and irreducible} is known explicitly (for all root systems). It is a union of alcoves in the complement of the reduciblity hyperplanes: α, ν = 1, α +. 14

Spherical unitary dual of a Hecke algebra of type B2 Complementary series are attached to nilpotent orbits in so(5, C). ν = 1 2 h + χ CS H(O) χ CS H(Z(O)) (0). The zero-complementary series for the centralizers are known. O 1 2 h χ Z(O) 1 2 h + χ CS H(O) 5 (1, 2) (0, 0) (1, 2) 311 (0, 1) (a, 0) (a, 1) a = 0 ( ( 221 1 2, ) 1 1 2 2 (a, a) + a, 1 2 + a) 0 a < 1 2 11111 (0, 0) (a, b) (a, b) 0 a b < 1 a < 1 15

Spherical unitary dual of a Hecke algebra of type B2 a = b H(B2) (2,1) CS(5) 0 1 2 a = 0 (1,0) CS(3, 1, 1) ( 1 2, 1 2 ) CS(2, 2, 1) (1, 0) 0 ( 1 2, 1 2 ) (1, 0) CS(1, 1, 1, 1, 1) 16

PART 2 Unitary dual of (double cover of) real split groups 17

Real split groups G K G (maximal compact) A n SL(n + 1, R) SO(n + 1) B n SO(n + 1, n) 0 SO(n + 1) SO(n) C n Sp(2n, R) U(n) D n SO(n, n) 0 SO(n) SO(n) G 2 G 2 SU(2) SU(2)/{±I} F 4 F 4 Sp(1) Sp(3)/{±I} E 6 E 6 Sp(4)/{±I} E 7 E 7 SU(8)/{±I} E 8 E 8 Spin(16)/{I, w} 18

Fine K-types For each root α we choose a Lie algebra homomorphism φ α : sl(2, R) g 0 whose image ( is a subalgebra ) of g 0 isomorphic to sl(2, R). Then 0 1 Z α := φ α is a generator for an so(2)-subalgebra of k 0. 1 0 A K-type µ K is level k if γ k for every root α and every eigenvalue γ of dµ(z α ). K-types of level 1 2 1 are fine. are called pseudospherical ; the ones of level Every δ M is contained in a fine K-type µ δ (maybe not unique). Every M-type in the W-orbit of δ appears in µ δ with multiplicity 1. 19

Parameters Minimal Principal Series P = M AN minimal parabolic subgroup (δ, V δ ) M ν Â a real and weakly dominant Principal Series X(δ, ν) = Ind G P=MAN(δ ν triv) µ K, mult(µ, X(δ, ν) K ) = mult(δ, µ M ). G P = MAN M Z 2 A R >0 δ ν ( ) ( ) a b a 0 triv SL 2 (R) ±I ν 0 0 a 1 0 a 1 sgn 8 < triv bk Z, n M = : sgn 8 if n 2Z < L if n 2Z + 1, X(δ, ν) n SO(2)= 2n if δ = triv : L 2n + 1 if δ = sgn n 20

The Langlands quotient L(δ, ν) For simplicity, assume, that δ is contained in a unique fine K-type µ δ. L(δ, ν)=unique irreducible quotient of X(δ, ν) containing µ δ If w 0 W is the longest element, there is an intertwining operator (normalized on µ δ ) such that A(w 0, δ, ν) has no poles A(w 0, δ, ν): X(δ, ν) X(w 0 δ, w 0 ν) The (closure of the) image of A(w 0, δ, ν)) is L(δ, ν). Hence L(δ, ν) = X(δ,ν) Ker(A(w 0,δ,ν)). 21

Unitarity of the Langlands quotient L(δ, ν) L(δ, ν) is Hermitian if and only if w 0 δ δ and w 0 ν = ν. In this case, the (normalized) operator A(w 0, δ, ν) := µ δ (w 0 )A(w 0, δ, ν): X(δ, ν) X(δ, ν) induces a non-degenerate invariant Hermitian form on L(δ, ν). For every µ K, there is an operator A µ (w 0, δ, ν) on Hom M (µ, δ). (A µδ (w 0, δ, ν) = 1.) L(δ, ν) is unitary if and only if the operator A µ (w 0, δ, ν) is positive semidefinite, µ K We should compute the signature of infinitely many operators. 22

The operator A µ (w 0, δ, ν) on the K-type µ Fix a K-type µ. The operator A µ (w 0, δ, ν) can be written as a product of operators corresponding to simple reflections. If w 0 = s α1 s α2 s α1 is a reduced decomposition of w 0 in W, then A µ (w 0, δ, ν) = n i=1 A µ (s αi, δ i 1, ν i 1 ) with ν i = s αn+1 i s αn 1 s αn ν, and δ i = s αn+1 i s αn 1 s αn δ. Note that the full operator A µ (w 0, δ, ν) acts on Hom M (µ, δ), but the factors might not. [The reflections move δ around in its W-orbit.] 23

The α-factor A µ (s α, ρ, γ) An α-factor of the full intertwining operator is a map A µ (s α, ρ, γ): Hom M (µ, ρ) Hom M (µ, s α ρ). Here ρ and s α ρ are two M-types in the W-orbit of δ. They can both be realized inside µ δ (our fixed fine K-type containing δ). Let Z α be a generator for the so(2)-subalgebra attached to α. Then Z 2 α acts on Hom M (µ, ρ); decompose Hom M (µ, ρ) in Z 2 α-eigenspaces: Hom M (µ, ρ) = l E α,ρ ( l 2 ) [Here l Z+ 1 2 if δ is genuine and α is metaplectic; l Z otherwise.] The operator A µ (s α, ρ, γ) maps E α,ρ ( l 2 ) E α,s αρ ( l 2 ), l, acting by: T c l (α, γ)µ δ (σ α ) T µ(σ 1 α ). 24

The scalars c l (α, γ) Let l 1 2 Z, l 0. Set ξ = γ, ˇα. Then c l(α, γ) is equal to 1 if l = 0, 1 or 1 2 (for the normalization) ( 1) l/2(1 ξ)(3 ξ) (2m 1 ξ) (1 + ξ)(3 + ξ) (l 1 + ξ) ( 1) (l 1)/2(2 ξ)(4 ξ) (l 1 ξ) (2 + ξ)(4 + ξ) (l 1 + ξ) if l 2N if l 2N + 1 ( 1) (l+1/2)/2(1 2 ξ)(5 2 ξ) (l 1 ξ) ( 1 2 + ξ)(3 2 + ξ) (l 1 + ξ) if l 3 2 + 2N ( 1) (l 1)/2(3 2 ξ)(7 2 ξ) (l 1 ξ) ( 3 2 + ξ)(7 2 + ξ) (l 1 + ξ) if l 5 2 + 2N 25

PART 3 Petite K-types 26

The idea of petite K-types The unitarity of L(δ, ν) is hard to detect: It depends on the signature of infinitely many operators (one for each K-type) The computations are hard if the K-type is large. To make the problem easier: 1. Select a small set of petite K-types on which the computations are easy. 2. Compute operators only for petite K-types, hoping that the calculation will rule out large non-unitarity regions. This approach will provide necessary conditions for unitarity: L(δ, ν) unitary A µ (w 0, δ, ν) pos. semidefinite, µ petite 27

Main feature of petite K-types The operators {A µ (δ, ν): µ petite} resemble operators for affine graded Hecke algebras. unitarizability of Langlands quotients for real split groups relate unitarizability of Langlands quotients for Hecke algebras 28

Petite K-types For each root α and each M-type ρ, there is an action of Z 2 α on the space Hom M (µ, ρ), defined by T T dµ(z α ) 2. If µ δ is a fine K-type containing δ, we look at the action of Zα 2 on the space Hom M (µ, µ δ ) = Hom M (µ, δ i ). δ i W-orbit of δ Definition. A K-type is called petite for δ if the eigenvalues of Z 2 α on Hom M (µ, µ δ ) are of the form k 2 with k 2, α. This is a restriction on the eigenvalues of Z 2 α on the isotypic component in µ of every M-type in the W-orbit of δ. Corollary. K-types of level 2 are petite for every δ. 29

Main theorem G: real split group associated to a root system δ: an M-type for G, with fine K-type µ δ W δ : stabilizer of δ in W; δ : good roots for δ δ if δ is genuine H: affine graded Hecke algebra for ˇ δ otherwise. Theorem. For each K-type µ, there is a representation ψ µ of the stabilizer W δ on the space Hom M (µ, δ). When µ is petite, the correspondence µ K = ψ µ Ŵ δ gives rise to a matching of intertwining operators: A G µ (w 0, δ, ν) = A H ψ µ (w 0, ν). 30

The spherical case: δ = δ 0 is trivial If δ = δ 0 is trivial, every reflection stabilizes δ. So W δ 0 = W δ0 = H = Hecke algebra with root system ˇ δ 0 non-genuine take ˇ δ0 Theorem. If µ is petite for δ 0 and ψ µ is the representation of W on Hom M (µ, δ 0 ), then A G µ (w 0, δ 0, ν) A H ψ µ (w 0, ν) 31

The spherical case: δ = δ 0 is trivial Decompose A µ (w 0, δ, ν) in α-factors A µ (s α, ρ, λ): Hom M (µ, ρ) Hom M (µ, s α ρ) (with ρ an M-type in the W-orbit of δ). If δ = δ 0, then ρ = s α ρ = δ 0, so every factor A µ (s α, ρ, λ) End(Hom M (µ, δ 0 )) Hom M (µ, δ 0 ) carries a repr. ψ µ of W, and an action of dµ(z 2 α). Decompose Hom M (µ, δ 0 ) in eigenspaces of dµ(z 2 α): Hom M (µ, δ 0 ) = m N E α ( 4m 2 ). A µ (s α, ρ, λ) acts on acts on E α ( 4m 2 ) by T c(α, γ, 2m) µ δ (σ α )T(µ(σ α ) 1 ). }{{}}{{} a scalar ψ µ (s α )T 32

Petite Spherical K-types If the K-type µ is petite for δ 0, then (V µ ) M = E α (0) E α ( 4). E α (0) 1 ψ µ(sα) E α (0) E α ( 4) E α ( 16) 1 γ, ˇα 1+ γ, ˇα ψ µ(sα) E α ( 4) E α ( 16) E... α ( 36)... E α ( 36) The spaces E α (0) and E α ( 4) coincide with the (+1)- and ( 1)-eigenspace of ψ µ (s α ), respectively. (+1)-eig. of ψµ(sα) ( 1)-eig. of ψµ(sα) 1 (+1)-eig. of ψµ(sα) Hence A µ (s α, δ 0, λ) = I+ γ, ˇα ψ µ(s α ) 1+ γ, ˇα. = 1 γ, ˇα 1+ γ, ˇα ( 1)-eig. of ψµ(sα) this is an operator for a Hecke algebra with root system ˇ 33

The pseudospherical case If δ is pseudospherical, every reflection stabilizes δ. So W δ = W δ = H = Hecke algebra with root system δ genuine take δ If µ is petite for δ and ψ µ is the representation of W on Hom M (µ, δ), then A G µ (w 0, δ, ν) A H ψ µ (w 0, ν) 34

Similar to the spherical case: The stabilizer of δ is W. The pseudospherical case Every α-factor is an endomorphism of Hom M (µ, δ). Hom M (µ, δ) carries a repr. ψ µ of W and an action of dµ(z α ) 2. Decompose Hom M (µ, δ) in Zα-eigenspaces: 2 Hom M (µ, δ) = E α ( l 2 ). (Here l 2N + 1 2 l N/2 if α is metaplectic, and l 2N otherwise.) A µ (s α, ρ, λ) acts on acts on E α ( l 2 ) by T c(α, γ, l) µ δ (σ α )T(µ(σ α ) 1 ). }{{}}{{} a scalar ψ µ (s α )T The scalar depends on whether α is metaplectic or not. 35

Petite K-types for δ pseudospherical (α metaplectic) In this case, (V µ ) M = E α ( 1/4) E α ( 9/4). E α ( 1/4) 1 ψ µ(sα) E α (0) E α ( 9/4) E α ( 25/4) 1/2 γ, ˇα 1/2+ γ, ˇα ψ µ(sα) E α ( 4) E α ( 16) E α ( 49/4)...... E α ( 49/4) The spaces E α ( 1/4) and E α ( 9/4) coincide with the (+1)- and ( 1)-eigenspace of ψ µ (s α ), respectively. (+1)-eig. of ψµ(sα) 1 (+1)-eig. of ψµ(sα) ( 1)-eig. of ψµ(sα) 1/2 γ, ˇα 1/2+ γ, ˇα ( 1)-eig. of ψµ(sα) = 1 γ, α 1+ γ, α Hence A µ (s α, δ 0, λ) = I+ γ, α ψ µ(s α ) 1+ γ, α. = operator for H( ) 36

Petite K-types for δ pseudospherical (α not metaplectic) In this case, (V µ ) M = E α (0) E α ( 4). E α (0) 1 ψ µ(sα) E α (0) E α ( 4) 1 γ, ˇα 1+ γ, ˇα ψ µ(sα) E α ( 4) E α ( 16) E α ( 36)...... E α ( 16) E α ( 36) The spaces E α (0) and E α ( 4) coincide with the (+1)- and ( 1)-eigenspace of ψ µ (s α ), respectively. (+1)-eig. of ψµ(sα) ( 1)-eig. of ψµ(sα) 1 (+1)-eig. of ψµ(sα) 1 γ, ˇα 1+ γ, ˇα ( 1)-eig. of ψµ(sα) Hence A µ (s α, δ 0, λ) = I+ γ, α ψ µ(s α ) 1+ γ, α. = operator for H( ) = 1 γ, α 1+ γ, α 37

The non-spherical non-pseudospherical case In this case, not every reflection stabilizes δ. W δ W and δ H = Hecke algebra with root system ˇ if δ genuine otherwise Theorem. If µ is petite for δ and ψ µ is the representation of W δ on Hom M (µ, δ), then A G µ (w 0, δ, ν) A H ψ µ (w 0, ν) These operators decompose as a product of α-factors, mimicking a minimal decomposition of w 0 in W and in W δ respectively. Hence A G µ (w 0, δ, ν) has more factors. 38

Choose a minimal decompositions of w 0 in W δ : w 0 = s β1 s β2 s βr. Every root s β which is simple in both W δ and W gives rise to a single factor of A G µ (w 0, δ, ν) of A G µ (w 0, δ, ν) = I+ γ, β ψ µ (s β ) 1+ γ, β I+ γ, ˇβ ψ µ (s β ) 1+ γ, ˇβ if δ is genuine otherwise. Every root s β which is simple in W δ but not simple in W gives rise to I+ γ, β ψ a product µ (s β ) 1+ γ, β if δ is genuine of factors = I+ γ, ˇβ ψ µ (s β ) 1+ γ, ˇβ otherwise. This product reflects a minimal factorization of s β in W. 39

PART 4 What petite K-type do for us: Embedding of unitary duals 40

A matching of petite K-types with relevant W δ -types If µ is petite, the correspondence µ K ψ µ = Hom M (µ, δ) Ŵ δ gives rise to a matching of operators: A G µ (w 0, δ, ν) A H ψ µ (w 0, ν). Theorem. If set {ψ µ : µ K petite} includes all the relevant W δ -types, then we obtain an embedding of unitary duals: δ-complementary series of G spherical unitary dual of H {ν : L G (δ, ν) unitary} {ν : L H (ν) unitary} 41

An embedding of unitary duals Suppose that for each relevant W δ -type ψ, there is a petite K-type µ such that ψ µ = ψ. ( ). L G (δ, ν) is unitary =============> L H ( ν) is unitary A G µ (w 0, δ, ν) A G µ (w 0, δ, ν) A H ψ (w 0, ν) A H ψ (w 0, ν) pos. semidef. pos. semidef. ( ) pos. semidef. ( ) pos. semidef. µ K µ petite ψ relevant ψ Ŵ ( ) Relevant W-types detect unitarity for H. [Barbasch-Ciubotaru] 42

Spherical unitary duals for split groups Theorem [Barbasch] If δ = δ 0, the matching holds for all real split groups G. Let H be the affine graded Hecke algebra with root system dual to the one of G. Then spherical unitary dual of G This gives us: spherical unitary dual of H this is an equality for classical groups the full spherical unitary dual of real split classical groups non-unitarity certificates for spherical representations of real split exceptional groups. 43

An example: the spherical unitary dual of Sp(4) Let H be an affine graded algebra of type B2. The spherical unitary dual of Sp(4) embeds into the one of H(B2): a = b H(B2) 0 1 2 a = 0 Actually, they are equal. 44

Pseudospherical unitary duals for split groups Theorem [Adams, Barbasch, Paul, Trapa, Vogan] Let δ be pseudospherical. The matching holds for the double cover of every real split group of classical type. Let H be the affine graded Hecke algebra with the same root system as G. Then pseudosph. unitary dual of G spherical unitary dual of H this is an equality for Mp(2n) This gives us: the full pseudospherical unitary dual of Mp(2n) non-unitarity certificates for the other classical groups. 45

An example: the pseudospherical unitary dual of Mp(4) Let H be an affine graded algebra Hecke of type C2. The pseudospherical unitary dual of Mp(4) coincides with the spherical unitary dual of H (which, in turn, coincides with the spherical unitary dual of of SO(3, 2)). ν 1 = ν 2 SO(3,2) 0 0 1 2 ν 2 = 0 46

Genuine complementary series of Mp(2n) Genuine M-types of Mp(2n) are parameterized by pairs of non-negative integers (p, q) with p + q = n. If δ = δ p,q, then δ = C p C q. Theorem [Paul, P., Salamanca] The matching holds for every genuine M-type δ p,q of Mp(2n). Let H be the affine graded Hecke algebra for the root system C p C q. Then δ p,q -compl. series of Mp(2n) spherical unitary dual of H an equality for n 4 (all p, q), and for some special families of parameters (all n) [Barbasch]: spherical unitary dual of H = spherical unitary dual of SO(p + 1, p) SO(q + 1, q). 47

CS(Mp(6), δ 2,1 ) = CS(SO(3, 2) 0, δ 0 ) CS(SO(2, 1) 0, δ 0 ) ν 2 1/2 3/2 ν 1 CS(SO(3,2) 0, δ 0 ) CS(SO(2,1) 0, δ 0 )...... -2-3 2-1 - 1 2 0 1 2 1 3 2 2 CS(Mp(6), δ 2,1 ) equals the product 48

Complementary series of SO(n + 1, n) 0 M-types of SO(n + 1, n) 0 are parameterized by pairs of non-negative integers (p, q) with p + q = n. If δ = δ p,q, then δ = B p B q. Theorem [Paul, P., Salamanca] The matching holds for every M-type δ p,q of SO(n + 1, n) 0. Let H be affine graded Hecke algebra for the root system C p C q. Then CS(SO(n + 1, n) 0, δ p,q ) spherical unitary dual of H an equality for n 4 (all p, q), and for some special families of parameters (all n) [Barbasch]: spherical unitary dual of H = spherical unitary dual of SO(p + 1, p) SO(q + 1, q). 49

CS(SO(4, 3) 0, δ 2,1 ) = CS(SO(3, 2) 0, δ 0 ) CS(SO(2, 1) 0, δ 0 ) 50

The double cover of split E6 joint with D.Barbasch repr. of M note dim δ matching δ 1 trivial 1 E6 δ 8 pseudosph. 8 E6 NO ( ) δ 27 non-genuine 27 1 D 5 δ 36 non-genuine 36 1 A 5 A 1 ( ) One relevant W(E6)-type is missing. 51

The double cover of split F4 joint with D.Barbasch repr. of M note dim δ matching δ 1 trivial 1 F4 δ 2 pseudosph. 2 F4 δ 3 non-genuine 3 1 C4 No ( ) δ 6 genuine 3 2 B4 No ( ) δ 12 non-genuine 12 1 B3 A 1 ( ) One relevant W(C4)-type is missing. ( ) Two relevant W(B4)-types are missing. 52