07-1352/Class Notes for January 23: Difference between revisions
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===The Algebra=== |
===The Algebra=== |
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Let <math>A_n={\mathbb Q}S_n\otimes{\mathbb Q}\langle |
Let <math>A_n={\mathbb Q}S_n[x]\otimes{\mathbb Q}\langle t_1\ldots t_n\rangle</math> be the vector-space tensor product of the group ring <math>{\mathbb Q}S_n</math> of the permutation group <math>S_n</math> (with coefficients in <math>{\mathbb Q}[x]</math>, polynomials in the variable <math>x</math>) with the free associative algebra <math>{\mathbb Q}\langle t_1\ldots t_n\rangle</math> on (non-commuting) generators <math>t_1\ldots t_n</math> (that is, <math>{\mathbb Q}\langle t_1\ldots t_n\rangle</math> is the ring of non-commutative polynomials in the variables <math>t_1\ldots t_n</math>). We put an algebra structure on <math>A_n</math> as follows: |
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Let <math>A^0_n=\langle S_n, x, t_1,\ldots t_n\rangle</math> be the free associative (but non-commutative) algebra generated by the elements of the symmetric group <math>S_n</math> on <math>\{1,\ldots,n\}</math> and by formal variables <math>x</math> and <math>t_1\ldots t_n</math>, and let <math>A^1_n</math> be the quotient of <math>A^0_n</math> by the following relations: |
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# <math>x</math> commutes with everything else. |
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# The product of permutations is as in the symmetric group <math>S_n</math>. |
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# If <math>\sigma</math> is a permutation then <math>t_i\sigma=\sigma t_{\sigma i}</math>. |
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# <math>[t_i,t_j]=x\sigma_{ij}(t_j-t_i)</math>, where <math>\sigma_{ij}</math> is the transposition of <math>i</math> and <math>j</math>. |
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Finally, declare that <math>\deg x=\deg t_i=1</math> while <math>\deg\sigma=0</math> for every <math>1\leq i\leq n</math> and every <math>\sigma\in S_n</math>, and let <math>A_n</math> be the graded completion of <math>A^1_n</math>. |
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===The Equations=== |
===The Equations=== |
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Revision as of 16:47, 22 January 2007
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In Preparation
The information below is preliminary and cannot be trusted! (v)
A HOMFLY Braidor
The Algebra
Let be the vector-space tensor product of the group ring of the permutation group (with coefficients in , polynomials in the variable ) with the free associative algebra on (non-commuting) generators (that is, is the ring of non-commutative polynomials in the variables ). We put an algebra structure on as follows:
![{\displaystyle A_{n}={\mathbb {Q} }S_{n}[x]\otimes {\mathbb {Q} }\langle t_{1}\ldots t_{n}\rangle }](https://wikimedia.org/api/rest_v1/media/math/render/svg/6881ed299372a18106293bc20dadaf6a69559f49)
![{\displaystyle {\mathbb {Q} }[x]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/93999e33b5ff78e8df97abca21459d1dbd47ac75)
Let be the free associative (but non-commutative) algebra generated by the elements of the symmetric group on and by formal variables and , and let be the quotient of by the following relations:
- commutes with everything else.
- The product of permutations is as in the symmetric group .
- If is a permutation then .
- , where is the transposition of and .
![{\displaystyle [t_{i},t_{j}]=x\sigma _{ij}(t_{j}-t_{i})}](https://wikimedia.org/api/rest_v1/media/math/render/svg/85328403dff8cc898e1108beac427ebc7ed119bf)
Finally, declare that while for every and every , and let be the graded completion of .
