Actions of Tantalizers

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last updates: 15 October 2012

Actions of tantalizers

Let $𝔤$ be a complex semisimple Lie algebra and let $U𝔤$ be the universal enveloping algebra. Let $C$ be the center of $U𝔤$ and let $κ$ be the Casimir in $C$ . Let $M$ and $V$ be $𝔤$ -modules.

Let $𝔹_{k}$ be the degenerate affine braid group. Then $M \otimes V^{\otimes k}$ is a $𝔹_{k}$ -module with action given by $\begin{array}{rcrcl} Φ & : & 𝔹_{k} & \to & {End}_{U} (M \otimes V^{\otimes k}), \\ t_{s_{i}} & \mapsto & {id}_{M} \otimes {id}_{V}^{\otimes i - 1} \otimes s_{1} \otimes {id}_{V}^{\otimes k - i - 1}, \\ c_{i} & \mapsto & κ_{M \otimes V^{\otimes i}} \otimes {id}_{V}^{\otimes k - i} \\ z & \mapsto & z \otimes {id}_{V}^{\otimes k}, \end{array}$ for $z \in C$ and where $s_{1} \cdot (u \otimes v) = v \otimes u,$ for $u, v \in V$ and $κ_{M \otimes V^{\otimes i}}$ is $κ$ acting on $M$ and the first $i$ factors of $V$ . This action commutes with the $𝔤$ -action on $M \otimes V^{\otimes k}$ .
Let $𝔤$ be ${𝔰 𝔬}_{2 r + 1}$ , ${𝔰 𝔬}_{2 r}$ or ${𝔰 𝔭}_{2 r}$ . Using notations for irreducible representations as in (5.27), let $ε = \{\begin{cases} 1, & if 𝔤 is {𝔰 𝔬}_{2 r + 1} or {𝔰 𝔬}_{2 r}, \\ - 1, & if 𝔤 is {𝔰 𝔭}_{2 r}, \end{cases} V = L (ϵ_{1}), y = ⟨ ϵ_{1}, ϵ_{1} + 2 ρ ⟩,$ and $z_{V}^{(𝓁)} = ε (id \otimes {tr}_{V}) ({(y + t)}^{𝓁}), for 𝓁 \in ℤ_{\geq 0} .$ Then the algebra homomorphism $Φ : 𝔹_{k} \to {End}_{U} (M \otimes V^{\otimes k})$ is a representation of the degenerate affine BMW algebra $𝒲_{k}$ .
Let $𝔤 = 𝔰 𝔩_{r + 1}$ and $V = L (ϵ_{1})$ . Then $Φ : 𝔹_{k} \to {End}_{U} (M \otimes V^{\otimes k})$ is a representation of the graded Hecke algebra.

Proof.

Since the $t_{s_{i}}$ act as simple transpositions, they generate an action of $S_{k}$ on $M \otimes V^{\otimes k}$ . This action commutes with the $𝔤$ -action. Since $κ \in C$ , $c_{i} \in {End}_{𝔤} (M \otimes V^{\otimes i}) \subseteq {End}_{𝔤} (M \otimes V^{\otimes j})$ for $i \leq j$ . Then, since $κ \in U 𝔤$ , $c_{i}$ commutes with $c_{j}$ for $i \leq j$ . So $c_{0}, \dots, c_{k}$ all commute with each other. By (ctoy), $y_{1}, \dots, y_{k}$ commute with each other.

Since $c_{1}, \dots, c_{i - 1}$ act as the identity on the $i$ th and $(i + 1)$ st components of $M \otimes V^{\otimes (i + 1)}$ , $t_{s_{i}} c_{j} = c_{j} t_{s_{i}}$ for $j < i$ . Since $t_{s_{i}}$ commutes with the action of $U 𝔤$ on $M \otimes V^{\otimes j}$ , it follows that $t_{s_{i}} c_{j} = c_{j} t_{s_{i}}$ for $j > i$ . Hence the relations in (gbp3), and thus in (gbp1), are satisfied.

Let $t = \sum b \otimes b^{*}$ as in (tdefn). If
$\begin{array}{l} κ_{i} is the operator κ acting in the i th factor of V in M \otimes V^{\otimes k}, and \\ t_{l, m} is the operator t acting in the l th and m th factor of V in M \otimes V^{\otimes k}, \end{array}$ (ktop)
(so that $κ_{0}$ is $κ$ acting on $M$ ) then the relations in (gbp4) hold. Applying the coproduct to compute the action of $κ$ on $m \otimes v_{1} \otimes \dots \otimes v_{j}$ gives the first identity in (cytokt) and so the relations in (gbp2) hold.
By (5.20), the computations in (5.30) determine the action of $t$ on the components of $V \otimes V$ . The decompositions in (5.31) and (5.32) determine the action of $t_{s_{1}}$ on $V \otimes V$ . The operator $Φ (e_{1})$ is determined from $Φ (t_{s_{1}})$ and $Φ (t)$ via (gbp6), $Φ (t) Φ (t_{s_{1}}) = 1 - Φ (e_{1}) .$ Then $Φ (t_{s_{1}})$ , $Φ (e_{1})$ , and $Φ (t)$ act on the components of $V \otimes V$ by $\begin{array}{lccc} L (0) & L (2 ϵ_{1}) & L (ϵ_{1} + ϵ_{2}) \\ Φ (t) & - y & 1 & - 1 \\ Φ (t_{s_{1}}) & ε & 1 & - 1 \\ Φ (e_{1}) & 1 + ε y & 0 & 0 \end{array}$ where $y$ and $t$ are as in (5.24) and (5.17) respectively. The first relation in (dbw1) follows. Since ${dim}_{q} (V) = ε + y$ , the first identity in (5.15) gives that $Φ (e_{1}) = ε E_{V} .$ By (5.12), the second identity in (5.15), and (5.4), $\begin{array}{rcl} Φ (e_{i} t_{s_{i - 1}} e_{i}) & = & ε (1 \otimes E_{V}) (R_{V V} \otimes 1) (1 \otimes E_{V}) ε \\ = & (id \otimes {tr}_{V}) (R_{V V}) \otimes E_{V} \\ = & C_{V}^{- 1} \otimes E_{V} = id \otimes E_{V} = ε Φ (e_{i}), \end{array}$ which establishes the second relation in (dbw1). By (cytokt), $Φ (y_{1}) = \frac{1}{2} κ_{1} + t_{0, 1} = \frac{1}{2} y + t_{0, 1},$ and by (5.12), $\begin{array}{rcl} Φ (e_{1} y_{1}^{𝓁} e_{1}) & = & ε (id \otimes E_{V}) {(\frac{1}{2} y + t)}^{𝓁} ε (id \otimes E_{V}) \\ = & (id \otimes {tr}_{V}) ({(\frac{1}{2} y + t)}^{𝓁}) \otimes E_{V} \\ = & ε (id \otimes {tr}_{V}) ({(\frac{1}{2} y + t)}^{𝓁}) Φ (e_{1}) \\ = & z_{V}^{(𝓁)} Φ (e_{1}), \end{array}$ which gives the first relation in (dbw2). Since the $y_{i}$ commute and $t_{s_{i}} (y_{i} + y_{i + 1}) = (y_{i} + y_{i + 1}) t_{s_{i}},$ $e_{i} (y_{i} + y_{i + 1}) = (t_{s_{i}} y_{i} - y_{i + 1} t_{s_{i}} + 1) (y_{i} + y_{i + 1}) = (y_{i} + y_{i + 1}) (t_{s_{i}} y_{i} - y_{i + 1} t_{s_{i}} + 1) = (y_{i} + y_{i + 1}) e_{i} .$ Use notations similar to that in (ktop), so that, for an element $b \in U 𝔤$ or $U 𝔤 \otimes U 𝔤$ , $b_{i}$ and $b_{i, i + 1}$ denote the action of an element $b$ on the $i$ th, respectively $i$ th and $(i + 1)$ st, factors of $V$ in $M \otimes V^{\otimes (i + 1)}$ . Then $\begin{array}{rcl} (y_{i} + y_{i + 1}) e_{i} & = & (\frac{1}{2} κ_{i} + \underset{r = 0}{\sum^{i - 1}} t_{r, i} + \frac{1}{2} κ_{i + 1} + \underset{r = 0}{\sum^{i}} t_{r, i + 1}) e_{i} \\ = & (\frac{1}{2} κ_{i, i + 1} + \sum_{r = 0}^{i - 1} (t_{r, i} + t_{r, i + 1})) e_{i} \\ = & (\frac{1}{2} κ_{i, i + 1} + \sum_{r = 0}^{i - 1} \sum_{b} b \otimes Δ {(b^{*})}_{i, i + 1}) e_{i} \\ = & 0, \end{array}$ because the action of $b^{*}$ and $κ$ on $L (0)$ is $0$ .
In this case, $V \otimes V = L (2 ε_{1}) \oplus L (ε_{1} + ε_{2}) with Λ^{2} (V) = L (ε_{1} + ε_{2})$ so that $\begin{array}{lcc} L (2 ε_{1}) & L (ε_{1} + ε_{2}) \\ Φ (t) & 1 & - 1 \\ Φ (t_{s_{1}}) & 1 & - 1 \end{array} and Φ (e_{1}) = Φ (t) - Φ (t_{s_{1}}) = 0 .$

□

Say I wish to discuss irreducible representations of SU(3). I think it should be perfectly acceptable to point out that: $\otimes = \oplus$ .

Remark. In Theorem 1.1, if $Φ (y_{1})$ has eigenvalues $u_{1}, \dots, u_{r}$ , then $Φ$ is a representation of the degenerate cyclotomic BMW algebra $𝒲_{r, k} (u_{1}, \dots, u_{r})$ .

Pictorially,

STUFF STUFF

$PICTURE GOES HERE.$ By (5.20) and (2.3), the eigenvalues of $y_{j}$ are related to the eigenvalues of the Casimir.

The Schur functors are the functors $\begin{matrix} F_{V}^{λ} & : & \{U 𝔤 -modules\} & \to & \{𝔹_{k} -modules\} \\ M & \mapsto & {Hom}_{U 𝔤} (M (λ), M \otimes V^{\otimes k}) \end{matrix}$ where ${Hom}_{U 𝔤} (M (λ), M \otimes V^{\otimes k})$ is the vector space of highest weight $λ$ in $M \otimes V^{\otimes k}$ .

Let $𝔤$ be a complex semisimple Lie algebra and let $U = U_{h} 𝔤$ be the corresponding Drinfel'd-Jimbo quantum group. Let $M$ and $V$ be $U$ -modules.

Then

M \otimes V^{\otimes k}

is a

C B_{k}

-module with action given by

\begin{array}{rcrclr} Φ & : & C B_{k} & \to & {End}_{U} (M \otimes V^{\otimes k}), \\ T_{i} & \mapsto & {\overset{ˇ}{R}}_{i}, & 1 \leq k \leq k - 1, \\ X^{ε_{1}} & \mapsto & {\overset{ˇ}{R}}_{0}^{2}, \\ z & \mapsto & z_{M}, \end{array}

phidefn

where

z_{M} = z \otimes {id}_{V}^{\otimes k},

{\overset{ˇ}{R}}_{i} = {id}_{M} \otimes {id}_{V}^{\otimes (i - 1)} {\overset{ˇ}{R}}_{V V} \otimes {id}_{V}^{\otimes (k - i - 1)} and {\overset{ˇ}{R}}_{0}^{2} = ({\overset{ˇ}{R}}_{M V} {\overset{ˇ}{R}}_{V M}) \otimes {id}_{V}^{\otimes (k - 1)},

with

{\overset{ˇ}{R}}_{M V}

as in INSERTREF. The

C B_{k}

-action commutes with the

U

-action on

M \otimes V^{\otimes k}

Let

𝔤

{𝔰 𝔬}_{2 r + 1}

{𝔰 𝔬}_{2 r}

{𝔰 𝔭}_{2 r}

. Let

ε = \{\begin{cases} 1, & if 𝔤 is {𝔰 𝔬}_{2 r + 1} or {𝔰 𝔬}_{2 r}, \\ - 1, & if 𝔤 is {𝔰 𝔬}_{2 r}, \end{cases} V = L (ϵ_{1}), z = ε q^{⟨ ϵ, ϵ + 2 ρ ⟩},

and

Z_{V}^{(l)} = ε (id \otimes {tr}_{V}) ({(z ℛ_{21} ℛ)}^{l}), for l \in ℤ_{\geq 0} .

Then the algebra homomorphism

Φ : C B_{k} \to {End}_{U} (M \otimes V^{\otimes k})

is a representation of the affine BMW algebra

𝒲_{k}

Let

𝔤 = 𝔰 𝔩_{r + 1}

and

V = L (ε_{1})

. Then

Φ : C B_{k} \to {End}_{U} (M \otimes V^{\otimes k})

is a representation of the affine Hecke algebra.

Proof.

The relations (2.26) and (2.29) are consequences of the definition of the action of $T_{i}$ and $X^{ε_{1}}$ . The relations (2.27) and (2.28) follow from the following computations: ${\overset{ˇ}{R}}_{i} {\overset{ˇ}{R}}_{i + 1} {\overset{ˇ}{R}}_{i} = PICTURE = PICTURE = {\overset{ˇ}{R}}_{i + 1} {\overset{ˇ}{R}}_{i} {\overset{ˇ}{R}}_{i + 1}$ and ${\overset{ˇ}{R}}_{0}^{2} {\overset{ˇ}{R}}_{1} {\overset{ˇ}{R}}_{0}^{2} {\overset{ˇ}{R}}_{1} = PICTURE = PICTURE = {\overset{ˇ}{R}}_{1} {\overset{ˇ}{R}}_{0}^{2} {\overset{ˇ}{R}}_{1} {\overset{ˇ}{R}}_{0}^{2} .$

By (5.23), the computations in (5.30) determine the action of

{\overset{ˇ}{R}}_{V V}^{2}

on the components of

V \otimes V

. The operator

Φ (T_{1}) = {\overset{ˇ}{R}}_{V V}

is the square root of

{\overset{ˇ}{R}}_{V V}^{2}

and, at

q = 1

, specializes to

t_{s_{1}}

, the operator that switches the factors in

V \otimes V

. Thus equations (5.31) and (5.32) determine the sign of

Φ (T_{1})

on each component. The operator

Φ (E_{1})

is determined from

Φ (T_{1})

via the first identity in (2.39),

Φ (E_{1}) = 1 - \frac{Φ (T_{1}) - Φ (T_{1}^{- 1})}{q - q^{- 1}} .

Then

{\overset{ˇ}{R}}_{V V}^{2},

Φ (T_{1})

and

Φ (E_{1})

act on the components of

V \otimes V

\begin{array}{lccc} L (0) & L (2 ε_{1}) & L (ε_{1} + ε_{2}) \\ {\overset{ˇ}{R}}_{V V}^{2} & q^{- 2 ε} & q^{2} & q^{- 2} \\ Φ (T_{1}) & ε q^{- y} & q & - q^{- 1} \\ Φ (E_{1}) & 1 + ε [y] & 0 & 0 \end{array} where [y] = \frac{q^{y} - q^{- y}}{q - q^{- 1}} .

The first relation in (phidefn) follows from

Φ (E_{1} T_{1}) = ε y^{- y} Φ (E_{1}) = z^{- 1} Φ (E_{1}) .

Since

{dim}_{q} (V) = ε + [y]

, the first identity in (5.15) gives that

Φ (E_{1}) = ε E_{V} .

LABEL

By (5.12), the second identity in (5.15), and (5.22),

\begin{array}{rcl} Φ (E_{i} T_{i - 1} E_{i}) & = & ε (1 \otimes E_{V}) ({\overset{ˇ}{R}}_{V V} \otimes 1) (1 \otimes E_{V}) ε = (id \otimes {qtr}_{V}) ({\overset{ˇ}{R}}_{V V}) \otimes E_{V} \\ = & C_{V}^{- 1} \otimes E_{V} = q^{⟨ ε_{1}, ε_{1} + 2 ρ ⟩} id \otimes E_{V} = q^{y} Φ (E_{i}), \end{array}

LABEL

which establishes the second relation in (2.36). By (5.12),

\begin{array}{rcl} Φ (E_{1} Y_{1}^{l} E_{1}) & = & ε (id \otimes E_{V}) {(z ℛ_{21} ℛ)}^{l} ε (id \otimes E_{V}) = (id \otimes {qtr}_{V}) ({(z ℛ_{21} ℛ)}^{l}) \otimes E_{V} \\ = & ε (id \otimes {qtr}_{V}) ({(z ℛ_{21} ℛ)}^{l}) Φ (E_{1}) = Z_{V}^{(l)} Φ (E_{1}), \end{array}

LABEL

which gives the first relation in (2.37). Since the

Y_{i}

commute, and

T_{i} Y_{i} Y_{i + 1} = Y_{i} Y_{i + 1} T_{i},

E_{i} Y_{i} Y_{i + 1} = (1 - \frac{T_{i} - T_{i}^{- 1}}{q - q^{- 1}}) Y_{i} Y_{i + 1} = Y_{i} Y_{i + 1} (1 - \frac{T_{i} - T_{i}^{- 1}}{q - q^{- 1}}) = Y_{i} Y_{i + 1} E_{i} .

The proof that

E_{i} Y_{i} Y_{i + 1} = E_{i}

is exactly as in the proof of [OR, Thm. 6.1(c)]: Since

Φ (E_{1}) = ε E_{V},

using

E_{1} T_{1} = z^{- 1} E_{1},

the pictorial equalites

\begin{matrix} ε z^{2} \cdot & = ε z^{2} \cdot & = ε z^{2} z^{- 1} \cdot \end{matrix}

it follows that

Φ (E_{1} Y_{1} Y_{2} T_{1}^{- 1}) = ε (1 \otimes E_{V}) Φ (z X^{ε_{1}}) Φ (z T_{1} X^{ε_{1}})

acts as

ε z^{2} z^{- 1} \cdot {\overset{ˇ}{R}}_{L (0), M} {\overset{ˇ}{R}}_{M, L (0)} ({id}_{M} \otimes E_{V}) .

By (5.10), this is equal to

ε z (C_{M} \otimes C_{L (0)}) C_{M \otimes L (0)}^{- 1} ({id}_{M} \otimes E_{V}) = ε z \cdot C_{M} C_{M}^{- 1} ({id}_{M} \otimes E_{V}) = z \cdot Φ (D_{1}) = Φ (E_{1} T_{1}^{- 1}),

so that

(E_{1} Y_{1} T_{1}^{- 1}) = Φ (E_{1} T_{1}^{- 1}) .

This establishes the second relation in (2.37).

When $𝔤 = 𝔰 𝔩_{r}$ , $V \otimes V = L (2 ε_{1}) \oplus L (ε_{1} + ε_{2})$ with $S^{2} (V) = L (2 ε_{1})$ and $\land^{2} (V) = L (ε_{1} + ε_{2})$ , and $\begin{array}{ccc} L (2 ε_{1}) & L (ε_{1} + ε_{2}) \\ Φ ({\overset{ˇ}{R}}_{V V}^{2}) & q^{2} & q^{- 2} \\ Φ (T_{1}) & q & - q^{- 1} \end{array} so that Φ (E_{1}) = \frac{Φ (T_{1}) - Φ (T_{1}^{- 1})}{q - q^{- 1}} = 0 .$ Thus the relations (2.44), (2.36) and (2.37) are satisfied.

□

Remark. In Theorem 1.2, if $Φ (Y_{1})$ has eigenvalues $u_{1}, \dots, u_{r}$ , then $Φ$ is a representation of the cyclotomic BMW algebra $𝒲_{r, k} (u_{1}, \dots, u_{r})$ .

By the definition of $Y_{i}$ in (2.33), $Φ (Y_{i}) = z {\overset{ˇ}{R}}_{M \otimes V^{\otimes (i - 1)}, V} {\overset{ˇ}{R}}_{V, M \otimes V^{\otimes (i - 1)}} = z PICTURE.$

The Schur functors are the functors $\begin{matrix} F_{V}^{λ} & : & \{U 𝔤 -modules\} & \to & \{{\tilde{ℬ}}_{k} -modules\} \\ M & \mapsto & {Hom}_{U 𝔤} (M (λ), M \otimes V^{\otimes k}) \end{matrix}$ where ${Hom}_{U 𝔤} (M (λ), M \otimes V^{\otimes k})$ is the vector space of highest weight $λ$ in $M \otimes V^{\otimes k}$ .

References

[AMR] S. Ariki, A. Mathas and H. Rui Cyclotomic Nazarov Wenzl algebras, Nagoya Math. J. 182, (2006), 47-134. MR2235339 (2007d:20005)

[DRV] Z. Daugherty, A. Ram, and R. Virk, Affine and graded BMW algebras, in preparation.

[OR] R. Orellana and A. Ram, Affine braids, Markov traces and the category $𝒪$ , Algebraic groups and homogeneous spaces, 423-473, Tata Inst. Fund. Res. Stud. Math., Tata Inst. Fund. Res., Mumbai, 2007. MR2348913 (2008m:17034)

page history