In mathematics, the Fitting lemma – named after the mathematician Hans Fitting – is a basic statement in abstract algebra.
Suppose M is a module over some ring.
If M is indecomposable and has finite length, then every endomorphism of M is either an automorphism or nilpotent.
[1] As an immediate consequence, we see that the endomorphism ring of every finite-length indecomposable module is local.
A version of Fitting's lemma is often used in the representation theory of groups.
This is in fact a special case of the version above, since every K-linear representation of a group G can be viewed as a module over the group algebra KG.
To prove Fitting's lemma, we take an endomorphism f of M and consider the following two chains of submodules: Because
has finite length, both of these chains must eventually stabilize, so there is some
{\displaystyle \mathrm {im} (f^{n})=\mathrm {im} (f^{n'})}
{\displaystyle \mathrm {ker} (f^{m})=\mathrm {ker} (f^{m'})}
k = max { n , m }
, and note that by construction
{\displaystyle \mathrm {im} (f^{2k})=\mathrm {im} (f^{k})}
{\displaystyle \mathrm {ker} (f^{2k})=\mathrm {ker} (f^{k}).}
We claim that
{\displaystyle \mathrm {ker} (f^{k})\cap \mathrm {im} (f^{k})=0}
{\displaystyle x\in \mathrm {ker} (f^{k})\cap \mathrm {im} (f^{k})}
satisfies
{\displaystyle \mathrm {ker} (f^{k})+\mathrm {im} (f^{k})=M}
, there exists some
{\displaystyle f^{k}(x)\in \mathrm {im} (f^{k})=\mathrm {im} (f^{2k})}
{\displaystyle x\in \mathrm {ker} (f^{k})+f^{k}(y)\subseteq \mathrm {ker} (f^{k})+\mathrm {im} (f^{k}).}
Consequently,
is the direct sum of
{\displaystyle \mathrm {im} (f^{k})}
(This statement is also known as the Fitting decomposition theorem.)
is indecomposable, one of those two summands must be equal to
and the other must be the zero submodule.
Depending on which of the two summands is zero, we find that
is either bijective or nilpotent.