Engel's theorem

In representation theory, a branch of mathematics, Engel's theorem states that a finite-dimensional Lie algebra ${\mathfrak {g}}$ is a nilpotent Lie algebra if and only if for each $X\in {\mathfrak {g}}$ , the adjoint map

\operatorname {ad} (X)\colon {\mathfrak {g}}\to {\mathfrak {g}},

given by $\operatorname {ad} (X)(Y)=[X,Y]$ , is a nilpotent endomorphism on ${\mathfrak {g}}$ ; i.e., $\operatorname {ad} (X)^{k}=0$ for some k.^[1] It is a consequence of the theorem, also called Engel's theorem, which says that if a Lie algebra of matrices consists of nilpotent matrices, then the matrices can all be simultaneously brought to a strictly upper triangular form. Note that if we merely have a Lie algebra of matrices which is nilpotent as a Lie algebra, then this conclusion does not follow (i.e. the naïve replacement in Lie's theorem of "solvable" with "nilpotent", and "upper triangular" with "strictly upper triangular", is false; this already fails for the one-dimensional Lie subalgebra of scalar matrices).

The theorem is named after the mathematician Friedrich Engel, who sketched a proof of it in a letter to Wilhelm Killing dated 20 July 1890 (Hawkins 2000, p. 176). Engel's student K.A. Umlauf gave a complete proof in his 1891 dissertation, reprinted as (Umlauf 2010).

Statements edit

Let ${\mathfrak {gl}}(V)$ be the Lie algebra of the endomorphisms of a finite-dimensional vector space V and ${\mathfrak {g}}\subset {\mathfrak {gl}}(V)$ a subalgebra. Then Engel's theorem states the following are equivalent:

Each $X\in {\mathfrak {g}}$ is a nilpotent endomorphism on V.
There exists a flag $V=V_{0}\supset V_{1}\supset \cdots \supset V_{n}=0,\,\operatorname {codim} V_{i}=i$ such that ${\mathfrak {g}}\cdot V_{i}\subset V_{i+1}$ ; i.e., the elements of ${\mathfrak {g}}$ are simultaneously strictly upper-triangulizable.

Note that no assumption on the underlying base field is required.

We note that Statement 2. for various ${\mathfrak {g}}$ and V is equivalent to the statement

For each nonzero finite-dimensional vector space V and a subalgebra ${\mathfrak {g}}\subset {\mathfrak {gl}}(V)$ , there exists a nonzero vector v in V such that $X(v)=0$ for every $X\in {\mathfrak {g}}.$

This is the form of the theorem proven in #Proof. (This statement is trivially equivalent to Statement 2 since it allows one to inductively construct a flag with the required property.)

In general, a Lie algebra ${\mathfrak {g}}$ is said to be nilpotent if the lower central series of it vanishes in a finite step; i.e., for $C^{0}{\mathfrak {g}}={\mathfrak {g}},C^{i}{\mathfrak {g}}=[{\mathfrak {g}},C^{i-1}{\mathfrak {g}}]$ = (i+1)-th power of ${\mathfrak {g}}$ , there is some k such that $C^{k}{\mathfrak {g}}=0$ . Then Engel's theorem implies the following theorem (also called Engel's theorem): when ${\mathfrak {g}}$ has finite dimension,

${\mathfrak {g}}$ is nilpotent if and only if $\operatorname {ad} (X)$ is nilpotent for each $X\in {\mathfrak {g}}$ .

Indeed, if $\operatorname {ad} ({\mathfrak {g}})$ consists of nilpotent operators, then by 1. $\Leftrightarrow$ 2. applied to the algebra $\operatorname {ad} ({\mathfrak {g}})\subset {\mathfrak {gl}}({\mathfrak {g}})$ , there exists a flag ${\mathfrak {g}}={\mathfrak {g}}_{0}\supset {\mathfrak {g}}_{1}\supset \cdots \supset {\mathfrak {g}}_{n}=0$ such that $[{\mathfrak {g}},{\mathfrak {g}}_{i}]\subset {\mathfrak {g}}_{i+1}$ . Since $C^{i}{\mathfrak {g}}\subset {\mathfrak {g}}_{i}$ , this implies ${\mathfrak {g}}$ is nilpotent. (The converse follows straightforwardly from the definition.)

Proof edit

We prove the following form of the theorem:^[2] if ${\mathfrak {g}}\subset {\mathfrak {gl}}(V)$ is a Lie subalgebra such that every $X\in {\mathfrak {g}}$ is a nilpotent endomorphism and if V has positive dimension, then there exists a nonzero vector v in V such that $X(v)=0$ for each X in ${\mathfrak {g}}$ .

The proof is by induction on the dimension of ${\mathfrak {g}}$ and consists of a few steps. (Note the structure of the proof is very similar to that for Lie's theorem, which concerns a solvable algebra.) The basic case is trivial and we assume the dimension of ${\mathfrak {g}}$ is positive.

Step 1: Find an ideal ${\mathfrak {h}}$ of codimension one in ${\mathfrak {g}}$ .

This is the most difficult step. Let

{\mathfrak {h}}

be a maximal (proper) subalgebra of

{\mathfrak {g}}

, which exists by finite-dimensionality. We claim it is an ideal of codimension one. For each

X\in {\mathfrak {h}}

, it is easy to check that (1)

\operatorname {ad} (X)

induces a linear endomorphism

{\mathfrak {g}}/{\mathfrak {h}}\to {\mathfrak {g}}/{\mathfrak {h}}

and (2) this induced map is nilpotent (in fact,

\operatorname {ad} (X)

is nilpotent as

X

is nilpotent; see Jordan decomposition in Lie algebras). Thus, by inductive hypothesis applied to the Lie subalgebra of

{\mathfrak {gl}}({\mathfrak {g}}/{\mathfrak {h}})

generated by

\operatorname {ad} ({\mathfrak {h}})

, there exists a nonzero vector v in

{\mathfrak {g}}/{\mathfrak {h}}

such that

\operatorname {ad} (X)(v)=0

for each

X\in {\mathfrak {h}}

. That is to say, if

v=[Y]

for some Y in

{\mathfrak {g}}

but not in

{\mathfrak {h}}

, then

[X,Y]=\operatorname {ad} (X)(Y)\in {\mathfrak {h}}

for every

X\in {\mathfrak {h}}

. But then the subspace

{\mathfrak {h}}'\subset {\mathfrak {g}}

spanned by

{\mathfrak {h}}

and Y is a Lie subalgebra in which

{\mathfrak {h}}

is an ideal of codimension one. Hence, by maximality,

{\mathfrak {h}}'={\mathfrak {g}}

. This proves the claim.

Step 2: Let $W=\{v\in V|X(v)=0,X\in {\mathfrak {h}}\}$ . Then ${\mathfrak {g}}$ stabilizes W; i.e., $X(v)\in W$ for each $X\in {\mathfrak {g}},v\in W$ .

Indeed, for

Y

in

{\mathfrak {g}}

and

X

in

{\mathfrak {h}}

, we have:

X(Y(v))=Y(X(v))+[X,Y](v)=0

since

{\mathfrak {h}}

is an ideal and so

[X,Y]\in {\mathfrak {h}}

. Thus,

Y(v)

is in W.

Step 3: Finish up the proof by finding a nonzero vector that gets killed by ${\mathfrak {g}}$ .

Write

{\mathfrak {g}}={\mathfrak {h}}+L

where L is a one-dimensional vector subspace. Let Y be a nonzero vector in L and v a nonzero vector in W. Now,

Y

is a nilpotent endomorphism (by hypothesis) and so

Y^{k}(v)\neq 0,Y^{k+1}(v)=0

for some k. Then

Y^{k}(v)

is a required vector as the vector lies in W by Step 2.

\square

Notes edit

Citations edit

^ Fulton & Harris 1991, Exercise 9.10..
^ Fulton & Harris 1991, Theorem 9.9..

Works cited edit

Erdmann, Karin; Wildon, Mark (2006). Introduction to Lie Algebras (1st ed.). Springer. ISBN 1-84628-040-0.
Fulton, William; Harris, Joe (1991). Representation theory. A first course. Graduate Texts in Mathematics, Readings in Mathematics. Vol. 129. New York: Springer-Verlag. doi:10.1007/978-1-4612-0979-9. ISBN 978-0-387-97495-8. MR 1153249. OCLC 246650103.
Hawkins, Thomas (2000), Emergence of the theory of Lie groups, Sources and Studies in the History of Mathematics and Physical Sciences, Berlin, New York: Springer-Verlag, ISBN 978-0-387-98963-1, MR 1771134
Hochschild, G. (1965). The Structure of Lie Groups. Holden Day.
Humphreys, J. (1972). Introduction to Lie Algebras and Representation Theory. Springer.
Umlauf, Karl Arthur (2010) [First published 1891], Über Die Zusammensetzung Der Endlichen Continuierlichen Transformationsgruppen, Insbesondre Der Gruppen Vom Range Null, Inaugural-Dissertation, Leipzig (in German), Nabu Press, ISBN 978-1-141-58889-3

[FOOTNOTEFultonHarris1991Exercise_9.10.-1] Fulton & Harris 1991, Exercise 9.10..

[FOOTNOTEFultonHarris1991Theorem_9.9.-2] Fulton & Harris 1991, Theorem 9.9..

[1]

[2]