Representations of Cherednik Algebras

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Representations of Matthew Lipman Mentor: Gus Lonergan Sixth Annual MIT-PRIMES Conference May 21, 2016

One nice set of operators are those d which can be written in terms of differentiation and multiplication by fixed polynomials, known as differential operators.

One nice set of operators are those d which can be written in terms of differentiation and multiplication by fixed polynomials, known as differential operators. The operator A = x x (take the derivative, then multiply by x) is one. However, the operator S 12 that replaces all x 1 s with x 2 s and vice-versa, is not.

One nice set of operators are those d which can be written in terms of differentiation and multiplication by fixed polynomials, known as differential operators. The operator A = x x (take the derivative, then multiply by x) is one. However, the operator S 12 that replaces all x 1 s with x 2 s and vice-versa, is not. The product rule yields x x = x x + 1 and x 2 x 1 = x 1 x 2. Consider the algebra generated by x 1, x 2,..., x n (multiplication by variables) and 1, 2,..., n (differentiation), subject to [x i, j ] = x i j j x i = δ ij, i.e. 1 if i = j and 0 otherwise.

Recall A = x x = x x 1.

Recall A = x x = x x 1. We have A 2 =x x x x

Recall A = x x = x x 1. We have A 2 =x x x x =x(x x + 1) x

Recall A = x x = x x 1. We have A 2 =x x x x =x(x x + 1) x =x 2 2 2 x + x x

Now, suppose we want to extend this to have, e.g. S 12. We can easily apply a similar logic to add all permutations into our algebra.

Now, suppose we want to extend this to have, e.g. S 12. We can easily apply a similar logic to add all permutations into our algebra. The Dunkl operators D i = x i c j i (x i x j ) 1 (1 S ij ) commute with each other (with c a fixed constant).

Now, suppose we want to extend this to have, e.g. S 12. We can easily apply a similar logic to add all permutations into our algebra. The Dunkl operators D i = x i c j i (x i x j ) 1 (1 S ij ) commute with each other (with c a fixed constant).they also share the familiar property of derivatives that deg Dp (deg p) 1.

Now, suppose we want to extend this to have, e.g. S 12. We can easily apply a similar logic to add all permutations into our algebra. The Dunkl operators D i = x i c j i (x i x j ) 1 (1 S ij ) commute with each other (with c a fixed constant).they also share the familiar property of derivatives that deg Dp (deg p) 1. It is apparently useful in certain fields, like the representation theory of S n.

D 1 x1 2 = x1 2 c (x 1 x i ) 1 (1 S 1i )x1 2 x 1 i 1

D 1 x1 2 = x1 2 c (x 1 x i ) 1 (1 S 1i )x1 2 x 1 i 1 =2x 1 c (x 1 x i ) 1 (x1 2 xi 2 ) i 1

D 1 x1 2 = x1 2 c (x 1 x i ) 1 (1 S 1i )x1 2 x 1 i 1 =2x 1 c (x 1 x i ) 1 (x1 2 xi 2 ) i 1 =2x 1 c i 1(x 1 + x i ) =2x 1 c(n 1)x 1 c x i

The set of linear transformations (i.e. matrices) from one (vector) space to itself, denoted End V is an algebra, with addition and scalar multiplication the obvious and multiplication being composition.

The set of linear transformations (i.e. matrices) from one (vector) space to itself, denoted End V is an algebra, with addition and scalar multiplication the obvious and multiplication being composition. A representation of an algebra is a V with a homomorphism (i.e. structure-preserving map) ρ to End V.

The set of linear transformations (i.e. matrices) from one (vector) space to itself, denoted End V is an algebra, with addition and scalar multiplication the obvious and multiplication being composition. A representation of an algebra is a V with a homomorphism (i.e. structure-preserving map) ρ to End V. For any V, there is an automatic representation of End V with the identity map, and for any A, with A an algebra, there is a obvious representation of A with ρ(x)(y) = 0 for all x A, y V. Finally, if your algebra is a field, a representation is just a vector space

Working in characteristic (mod) p > 0.

Working in characteristic (mod) p > 0. Cherednik algebras deform differential operators so that we use D i instead of x i

Working in characteristic (mod) p > 0. Cherednik algebras deform differential operators so that we use D i instead of x i In quantum mechanics, we can adjust the x i term in Dunkl operators by a factor of. Then, the x i are position vectors, D i are momenta, and the extra part is accounting for Heisenberg s Uncertainty Principle.

1 x i x i x j x i x j x k x 1 x 2 x 3 x i x j x k x l x 2 x 6 x 7 x 8 x i x 1 x 2 x 3

Dunkl: Singular Polynomials for the Symmetric Groups proved results concerning the kernel of D i D j.

Dunkl: Singular Polynomials for the Symmetric Groups proved results concerning the kernel of D i D j. Pavel et al.: Representations of Rational with Minimal Support and Torus Knots discuss Cherednik algebras with characteristic 0.

Dunkl: Singular Polynomials for the Symmetric Groups proved results concerning the kernel of D i D j. Pavel et al.: Representations of Rational with Minimal Support and Torus Knots discuss Cherednik algebras with characteristic 0. Devadas and Sun: The Polynomial Representation of the Type A n1 Rational Cherednik Algebra in Characteristic p n proves similar kinds of results for characteristic p n by extending certain results from Pavel to positive characteristic.

We are trying the case p n 1, and will ideally develop techniques or conjectures which will be used for p n + 1 and ideally more. We currently have three unproven conjectures

We are trying the case p n 1, and will ideally develop techniques or conjectures which will be used for p n + 1 and ideally more. We currently have three unproven conjectures 1. Devadas and Sun relied on a nice set of functions f i and the fact that n Df i so that the f i are singular in their case. We believe (n 1) Df i f j.

We are trying the case p n 1, and will ideally develop techniques or conjectures which will be used for p n + 1 and ideally more. We currently have three unproven conjectures 1. Devadas and Sun relied on a nice set of functions f i and the fact that n Df i so that the f i are singular in their case. We believe (n 1) Df i f j. 2. We know that D 2 x 2p+2 i = 0 for small n 1 (mod p). We hope to show that D r x rp+r i = 0 whenever n r 1 (mod p)

We are trying the case p n 1, and will ideally develop techniques or conjectures which will be used for p n + 1 and ideally more. We currently have three unproven conjectures 1. Devadas and Sun relied on a nice set of functions f i and the fact that n Df i so that the f i are singular in their case. We believe (n 1) Df i f j. 2. We know that D 2 x 2p+2 i = 0 for small n 1 (mod p). We hope to show that D r x rp+r i = 0 whenever n r 1 (mod p) 3. We also conjecture that, for t 3 (and showed this for t = 0, 1, 2): t Dy t 1 x1 s = ( c) r s! (s r)! f (r) r=0 where f (0) = a=s t x 1 a, f (1) = a+b=s t f (2) = a+b+c=s t 1 i j 1 x 1 ax i b xj c, etc. i 1 x a 1 x b i,

I would like to thank: My mentor, Gus Lonergan My parents and the PRIMES Program, especially Pavel for his help with the project and Tanya for her help with the presentation.

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