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Tensor products of Lie nilpotent associative algebras and applications to codimension sequences

Elitza Hristova

Abstract

Let $G$ and $H$ be unital associative algebras over a field $K$, such that $G$ satisfies the identity $[x_1, \dots, x_p] = 0$ for some integer $p \geq 3$ and $H$ satisfies the identities $[x_1, x_2, x_3] = 0$ and $[x_1, x_2] \cdots [x_{2k-1}, x_{2k}]=0$ for some $k \geq 2$. In this paper, extending results of Deryabina and Krasilnikov, we show that the tensor product $G \otimes H$ is again a Lie nilpotent associative algebra, i.e., it satisfies $[x_1, \dots, x_{q}] = 0$ for some $q \geq p$. We also determine an explicit value of $q$ in the case $k = 2$, i.e., when $H$ satisfies the identity $[x_1, x_2][x_3, x_4] = 0$. As a corollary, we reprove a result of Drensky saying that any product of Grassmann algebras of the form $E\otimes E_{i_1}\otimes \cdots \otimes E_{i_s}$ or $E_{j_1} \otimes E_{j_2} \otimes \cdots \otimes E_{j_t}$, where $E$ denotes the Grassmann algebra over a countable dimensional vector space and $E_r$ denotes the Grasmann algebra over an $r$-dimensional vector space, satisfies an identity of the form $[x_1, \dots, x_q] = 0$ for some integer $q \geq 3$. In addition, we show that for products of the form $E\otimes E_{i_1}\otimes \cdots \otimes E_{i_s}$ the minimal value of $q$ is always and odd integer. We also provide several particular cases in which a value of $q$ can be explicitly computed. As an application, we consider a field of characteristic zero, the variety $\mathfrak{N}_p$ of Lie nilpotent associative algebras of index at most $p$ and the corresponding relatively free algebras of finite rank, $F_n(\mathfrak{N}_p)$. We exhibit many explicit irreducible $S_n$-modules in the $S_n$-module decomposition of the space of proper multilinear polynomials in $F_n(\mathfrak{N}_p)$ for any $p$. This gives a lower bound for the dimensions of the spaces of multilinear and proper multilinear polynomials in $F_n(\mathfrak{N}_p)$.

Tensor products of Lie nilpotent associative algebras and applications to codimension sequences

Abstract

Let and be unital associative algebras over a field , such that satisfies the identity for some integer and satisfies the identities and for some . In this paper, extending results of Deryabina and Krasilnikov, we show that the tensor product is again a Lie nilpotent associative algebra, i.e., it satisfies for some . We also determine an explicit value of in the case , i.e., when satisfies the identity . As a corollary, we reprove a result of Drensky saying that any product of Grassmann algebras of the form or , where denotes the Grassmann algebra over a countable dimensional vector space and denotes the Grasmann algebra over an -dimensional vector space, satisfies an identity of the form for some integer . In addition, we show that for products of the form the minimal value of is always and odd integer. We also provide several particular cases in which a value of can be explicitly computed. As an application, we consider a field of characteristic zero, the variety of Lie nilpotent associative algebras of index at most and the corresponding relatively free algebras of finite rank, . We exhibit many explicit irreducible -modules in the -module decomposition of the space of proper multilinear polynomials in for any . This gives a lower bound for the dimensions of the spaces of multilinear and proper multilinear polynomials in .
Paper Structure (7 sections, 26 theorems, 97 equations)

This paper contains 7 sections, 26 theorems, 97 equations.

Key Result

Theorem 1.1

B Let $M(\lambda)$ denote the irreducible $S_n$-module corresponding to the partition $\lambda$. Let $\Gamma_n(\mathfrak{N}_p) = \bigoplus_{\lambda} m_{\lambda} M(\lambda).$ Then there exist integers $s_1$ and $s_2$ such that the non-zero multiplicities $m_{\lambda}$ are supported in diagrams of th Moreover, only the first column in the Young diagram of $\lambda$ can grow arbitrarily large when $

Theorems & Definitions (44)

  • Theorem 1.1
  • Theorem 2.1
  • Theorem 2.2
  • Lemma 2.3
  • Remark 2.4
  • proof
  • Theorem 2.5
  • proof
  • Corollary 2.6
  • Corollary 2.7
  • ...and 34 more