Enveloping algebras of Lie algebras

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

Last updates: 10 April 2011

Basic properties

1.1 A Lie algebra is a vector space $𝔤$ over $k$ with a bracket $[,]:𝔤\otimes 𝔤\to 𝔤$ which satisfies $$\begin{array}{c}[x,x]=0,\text{for all} x\in 𝔤,\\ [x,[y,z\left]\right]+[z,[x,y\left]\right]+[y,[z,x\left]\right]=0,\text{for all} x,y,z\in 𝔤.\end{array}$$ The first relation is the skew-symmetric relation and is equivalent to $[x,y]=-[y,x]$, for all $x,y\in 𝔤$ provided $char\left(k\right)\ne 2$. The second relation is called the Jacobi identity.

1.2 Let $𝔤$ be a Lie algebra. Let $T\left(𝔤\right)$ be the tensor algebra of $𝔤$ and let $J$ be the ideal of $T\left(𝔤\right)$ generated by the tensors $$x\otimes y-y\otimes x-[x,y],$$ where $x,y\in 𝔤$. The enveloping algebra of $𝔤$, $𝔘𝔤$ is the associative algebra $$𝔘𝔤=\frac{T\left(𝔤\right)}{J}.$$ There is a canonical map $$\begin{array}{cccc}{\alpha }_0:& 𝔤& \to & 𝔘𝔤\\ & x& \mapsto & x+J& .\end{array}$$ The algebra $𝔘𝔤$ can be given the following universal property:

1. Let $\alpha :𝔤\to A$ be a mapping of $𝔤$ to an associative algebra $A$ such that for all $x,y\in 𝔤$ and let $1$ and $1_A$ denote the identities in $𝔘𝔤$ and $A$ respectively. Then there exists a unique mapping $\tau :𝔘𝔤\to A$ such that $\tau \left(1\right)=1_A$ and $\alpha =\tau \circ {\alpha }_0$, i.e., the following diagram commutes.

1.3 The following statement is the Poincaré-Birkoff-Witt theorem. See [Bou] or [J] for an exposition and a proof.

Suppose that $𝔤$ has a totally ordered basis $(x_i{)}_{i\in \Lambda }$. Then the elements $x_{i_1}{x}_{i_2}\cdots x_{i_{\mathrm{n}}}$ of the enveloping algebra $𝔘𝔤$, where $\left(i_1\le i_2\le \cdots \le i_n\right)$ is an arbitrary increasing finite seqeuce of elements of $\Lambda$, form a basis of $𝔘𝔤$.

1.4 It follows from the Poincaré-Birkoff-Witt theorem that the canonical map of $𝔤$ into $𝔘𝔤$ is injective. Thus we can view $𝔤$ as a subspace of $𝔘𝔤$. Also it is natural to give $𝔘𝔤$ a filtraition by defining $${𝔘}_n=span-\left\{x_{i_1}{x}_{i_2}\cdots x_{i_k}\mid k\le n,x_{i_j}\in 𝔤\right\}.$$ Then $$𝔘𝔤=\sum {𝔘}_m,{𝔘}_m\subseteq {𝔘}_n,\text{if} m\le n,\text{and}{𝔘}_m{𝔘}_n\subseteq {𝔘}_{m+n}.$$

1.5 The enveloping algebra of $𝔤$ is made into a Hopf algebra by defining a comultiplication $\Delta :𝔘𝔤\to 𝔘𝔤\otimes 𝔘𝔤$ by $$\Delta \left(x\right)=1\otimes x+x\otimes 1,\text{for all} x\in 𝔤,$$ a counit $ϵ:𝔘𝔤\to k$ by $$ϵ\left(x\right)=0,\text{for all}x\in 𝔤,$$ and an antipode $S:𝔘𝔤\to 𝔘𝔤$ by $$S\left(x\right)=-x,\text{for all} x\in 𝔤.$$

1.6 The algebra $𝔘𝔤\otimes 𝔘𝔤$ also has a filtration given by $$(𝔘𝔤\otimes 𝔘𝔤{)}_n=\sum _{r+s=n}{𝔘}_r\otimes {𝔘}_s.$$ If $y\in {𝔘}_m$ then $\Delta \left(y\right)\in (𝔘𝔤\otimes 𝔘𝔤{)}_m$ since if $x\in 𝔤$ then $\Delta \left(x\right)=1\otimes x+x\otimes 1\in \in (𝔘𝔤\otimes 𝔘𝔤{)}_1$.

1.7 An element $x$ of a Hopf algebra $A$ is primitive if $\Delta \left(x\right)=1\otimes x+x\otimes 1$. All elements of $𝔤$ are primitive elements of $𝔘𝔤$. In fact, the following Proposition shows that if $char\left(k\right)=0$ then the elements of $𝔤$ are all the primitive elements of $𝔘𝔤$.

If $char\left(k\right)=0$ then the subspace $𝔤$ of $𝔘𝔤$ is the set of primitive elements of $𝔘𝔤$.

		Proof:
	Suppose that $x_1,x_2,\dots$ is a basis of $𝔤$. Then the monomials $x_1^{k_1}{x}_1^{k_2}\cdots x_1^{k_m}$ form a basis of $𝔘𝔤$ and the tensors $$x_1^{k_1}{x}_2^{k_2}\cdots x_m^{k_m}\otimes x_1^{l_1}{x}_2^{l_2}\cdots x_n^{l_n}$$ form a basis of $𝔘𝔤\otimes 𝔘𝔤$. Then $$\begin{array}{rcl}\Delta \left(x_1^{k_1}{x}_2^{k_2}\cdots x_m^{k_m}\right)& =& {\left(x_1\otimes 1\otimes 1\otimes x_1\right)}^{k_1}\cdots {\left(x_m\otimes 1\otimes 1\otimes x_m\right)}^{k_m}\\ & =& x_1^{k_1}{x}_2^{k_2}\cdots x_m^{k_m}\otimes 1\\ & & +k_1{x}_1^{k_1-1}{x}_2^{k_2}\cdots x_m^{k_m}\otimes x_1+k_2{x}_1^{k_1}{x}_2^{k_2-1}\cdots x_m^{k_m}\otimes x_2+\cdots +k_m{x}_1^{k_1}{x}_2^{k_2}\cdots x_m^{k_m-1}\otimes x_m\\ & & +\cdots +1\otimes x_1^{k_1}{x}_1^{k_2}\cdots x_1^{k_m}.\end{array}$$ Note that The term $x_1^{k_1-1}{x}_2^{k_2}\cdots x_m^{k_m}\otimes x_1$ cannot appear with non-xero coefficeint in $\Delta \left(x_1^{l_1}{x}_2^{l_2}\cdots x_n^{l_n}\right)$ for any basis element $x_1^{l_1}{x}_2^{l_2}\cdots x_n^{l_n}$ different from $\otimes x_1^{k_1}{x}_2^{k_2}\cdots x_m^{k_m}$ The coproduct $\Delta \left(x_1^{k_1}{x}_2^{k_2}\cdots x_m^{k_m}\right)$ is a linear combination of terms of the form $x_1^{j_1}{x}_2^{j_2}\cdots x_m^{j_m}\otimes 1$ and $1\otimes x_1^{l_1}{x}_2^{l_2}\cdots x_m^{l_m}$ only if all the $k_i$ are $0$ except for one, and this one is $1$, i.e., only if $$x_1^{k_1}{x}_2^{k_2}\cdots x_m^{k_m}=x_i\in 𝔤$$ for some $i$. It follows from 1) that if $a\in 𝔘𝔤$ and the expansion of $\Delta \left(a\right)$ contains only terms of the form $x_1^{j_1}{x}_2^{j_2}\cdots x_m^{j_m}\otimes 1$ and $1\otimes x_1^{l_1}{x}_2^{l_2}\cdots x_m^{l_m}$ then $a$ is a linear combination of terms $x_1^{k_1}{x}_2^{k_2}\cdots x_m^{k_m}$ such that $\Delta \left(x_1^{k_1}{x}_2^{k_2}\cdots x_m^{k_m}\right)$ is a linear combination of terms of the form $x_1^{j_1}{x}_2^{j_2}\cdots x_m^{j_m}\otimes 1$ and $1\otimes x_1^{l_1}{x}_2^{l_2}\cdots x_m^{l_m}$. It now follows from 2) that $a$ is a linear combination of elements $x_i\in 𝔤$. Thus, if $a$ is a primitive element of $𝔘𝔤$, then $a\in 𝔤$. $\square$

References

Chapter I §2 of [Bou] gives a nice, in depth, exposition of enveloping algebras and the Poincaré-Birkoff-Witt theorem. Chapter II §1 discusses the bialgebra structure on the universal enveloping algebra. In particular [Bou] Chapt II. §1.5 Corollary to Proposition 9 gives a very slick proof of Proposition 1.2. The reason it is so slick is because of the marvelous combinatorial fact Bourbacki, Algebra Chapt. I §8.2 Prop. 2.

[Bou] N. Bourbaki, Lie groups and Lie algebras, Chapters I-III, Springer-Verlag, 1989.

[D] V.G. Drinfeld, Quantum Groups, Vol. 1 of Proccedings of the International Congress of Mathematicians (Berkeley, Calif., 1986). Amer. Math. Soc., Providence, RI, 1987, pp. 198–820. MR0934283

[DHL] H.-D. Doebner, Hennig, J. D. and W. Lücke, Mathematical guide to quantum groups, Quantum groups (Clausthal, 1989), Lecture Notes in Phys., 370, Springer, Berlin, 1990, pp. 29–63. MR1201823

The following book is a standard introductory book on Lie algebras; a book which remains a standard reference. This book has been released for a very reasonable price by Dover publishers.

[J] N. Jacobson, Lie algebras, Interscience Publishers, New York, 1962.

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