Seminar talk, 15 March 2023: Difference between revisions

Latest revision as of 08:40, 4 January 2025

Title: Quasiderivations and commutative subalgebras of the algebra $U {𝔤 𝔩}_{n}$

Abstract:
Let ${𝔤 𝔩}_{n}$ be the Lie algebra of $n \times n$ matrices over a characteristic zero field $k$ (one can take $k = ℝ$ or $ℂ$ ); let $S ({𝔤 𝔩}_{n})$ be the Poisson algebra of polynomial functions on ${𝔤 𝔩}_{n}^{*}$ , and $U {𝔤 𝔩}_{n}$ the universal enveloping algebra of ${𝔤 𝔩}_{n}$ . By Poincaré-Birkhoff-Witt theorem $S ({𝔤 𝔩}_{n})$ is isomorphic to the graded algebra $g r (U {𝔤 𝔩}_{n})$ , associated with the order filtration on $U {𝔤 𝔩}_{n}$ . Let $A \subseteq S ({𝔤 𝔩}_{n})$ be a Poisson-commutative subalgebra; one says that a commutative subalgebra $\hat{A} \subseteq U {𝔤 𝔩}_{n}$ is a quantisation of $A$ , if its image under the natural projection $U {𝔤 𝔩}_{n} \to g r (U {𝔤 𝔩}_{n}) ≅ S ({𝔤 𝔩}_{n})$ is equal to $A$ . In my talk I will speak about the so-called "argument shift" subalgebras $A = A_{ξ}$ in $S ({𝔤 𝔩}_{n})$ , generated by the iterated derivations of central elements in $S ({𝔤 𝔩}_{n})$ by a constant vector field $ξ$ . There exist several ways to define a quantisation of $A_{ξ}$ , most of them are related with the considerations of some infinite-dimensional Lie algebras. In my talk I will explain, how one can construct such quantisation of $A_{ξ}$ using as its generators iterated quasi-derivations $\hat{ξ}$ of $U {𝔤 𝔩}_{n}$ . These operations are "quantisations" of the derivations on $S ({𝔤 𝔩}_{n})$ and verify an analog of the Leibniz rule. In fact, I will show that iterated quasiderivation of certain generating elements in $U {𝔤 𝔩}_{n}$ are equal to the linear combinations of the elements, earlier constructed by Tarasov.

Video

@@ Line 2: / Line 2: @@
 | speaker = Georgy Sharygin
 | title = Quasiderivations and commutative subalgebras of the algebra <math>U\mathfrak{gl}_n</math>
-| abstract = Let <math>\mathfrak{gl}_n</math> be the Lie algebra of <math>n\times n</math> matrices over a characteristic zero field <math>\Bbbk</math> (one can take <math>\Bbbk=\mathbb R</math> or <math>\mathbb C</math>); let <math>S(\mathfrak{gl}_n)</math> be the Poisson algebra of polynomial functions on <math>\mathfrak{gl}_n^*</math>, and <math>U\mathfrak{gl}_n</math> the universal enveloping algebra of <math>\mathfrak{gl}_n</math>. By Poncar\'e-Birkhoff-Witt theorem <math>S(\mathfrak{gl}_n)</math> is isomorphic to the graded algebra <math>gr(U\mathfrak{gl}_n)</math>, associated with the order filtration on <math>U\mathfrak{gl}_n</math>. Let <math>A\subseteq S(\mathfrak{gl}_n)</math> be a Poisson-commutative subalgebra; one says that a commutative subalgebra <math>\hat A\subseteq U\mathfrak{gl}_n</math> is a \textit{quantisation} of <math>A</math>, if its image under the natural projection <math>U\mathfrak{gl}_n\to gr(U\mathfrak{gl}_n)\cong S(\mathfrak{gl}_n)</math> is equal to <math>A</math>.                                                                                                                                                                                                                                       In my talk I will speak about the so-called "argument shift" subalgebras <math>A=A_\xi</math> in <math>S(\mathfrak{gl}_n)</math>, generated by the iterated derivations of central elements in <math>S(\mathfrak{gl}_n)</math> by a constant vector field <math>\xi</math>. There exist several ways to define a quantisation of <math>A_\xi</math>, most of them are related with the considerations of some infinite-dimensional Lie algebras. In my talk I will explain, how one can construct such quantisation of <math>A_\xi</math> using as its generators iterated \textit{quasi-derivations} <math>\hat\xi</math> of <math>U\mathfrak{gl}_n</math>. These operations are "quantisations" of the derivations on <math>S(\mathfrak{gl}_n)</math> and verify an analog of the Leibniz rule. In fact, I will show that iterated quasiderivation of certain generating elements in <math>U\mathfrak{gl}_n</math> are equal to the linear combinations of the elements, earlier constructed by Tarasov.
+| abstract = Let <math>\mathfrak{gl}_n</math> be the Lie algebra of <math>n\times n</math> matrices over a characteristic zero field <math>\Bbbk</math> (one can take <math>\Bbbk=\mathbb R</math> or <math>\mathbb C</math>); let <math>S(\mathfrak{gl}_n)</math> be the Poisson algebra of polynomial functions on <math>\mathfrak{gl}_n^*</math>, and <math>U\mathfrak{gl}_n</math> the universal enveloping algebra of <math>\mathfrak{gl}_n</math>. By Poincaré-Birkhoff-Witt theorem <math>S(\mathfrak{gl}_n)</math> is isomorphic to the graded algebra <math>gr(U\mathfrak{gl}_n)</math>, associated with the order filtration on <math>U\mathfrak{gl}_n</math>. Let <math>A\subseteq S(\mathfrak{gl}_n)</math> be a Poisson-commutative subalgebra; one says that a commutative subalgebra <math>\hat A\subseteq U\mathfrak{gl}_n</math> is a ''quantisation'' of <math>A</math>, if its image under the natural projection <math>U\mathfrak{gl}_n\to gr(U\mathfrak{gl}_n)\cong S(\mathfrak{gl}_n)</math> is equal to <math>A</math>.                                                                                                                                                                                                                                       In my talk I will speak about the so-called "argument shift" subalgebras <math>A=A_\xi</math> in <math>S(\mathfrak{gl}_n)</math>, generated by the iterated derivations of central elements in <math>S(\mathfrak{gl}_n)</math> by a constant vector field <math>\xi</math>. There exist several ways to define a quantisation of <math>A_\xi</math>, most of them are related with the considerations of some infinite-dimensional Lie algebras. In my talk I will explain, how one can construct such quantisation of <math>A_\xi</math> using as its generators iterated ''quasi-derivations'' <math>\hat\xi</math> of <math>U\mathfrak{gl}_n</math>. These operations are "quantisations" of the derivations on <math>S(\mathfrak{gl}_n)</math> and verify an analog of the Leibniz rule. In fact, I will show that iterated quasiderivation of certain generating elements in <math>U\mathfrak{gl}_n</math> are equal to the linear combinations of the elements, earlier constructed by Tarasov.
-| video =
+| video = https://video.gdeq.org/GDEq-zoom-seminar-20230315-Georgy_Sharygin.mp4
 | slides =
 | references =
 | 79YY-MM-DD = 7976-96-84
 }}

Seminar talk, 15 March 2023: Difference between revisions

Latest revision as of 08:40, 4 January 2025

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