Splitting lemma

Not to be confused with the splitting lemma in singularity theory.

In mathematics, and more specifically in homological algebra, the splitting lemma states that in any abelian category, the following statements for a short exact sequence are equivalent.

Given a short exact sequence with maps or arrows, $q$ and $r$ , between the category objects:

0\longrightarrow A{\overset {q}{\longrightarrow }}B{\overset {r}{\longrightarrow }}C\longrightarrow 0

one writes the additional arrows t and u for maps that may not exist:

0\longrightarrow A{{\overset {q}{\longrightarrow }} \atop {\underset {t}{\longleftarrow }}}B{{\overset {r}{\longrightarrow }} \atop {\underset {u}{\longleftarrow }}}C\longrightarrow 0.

Then the following statements are equivalent:

Left split
There exists a map $t : B \to A$ such that $tq$ is the identity on $A$ , $id A$ ,
Right split
There exists a map $u : C \to B$ such that $ru$ is the identity on $C$ , $id C$ ,
Direct sum
$B$ is isomorphic to the direct sum of $A$ and $C$ , with $q$ corresponding to the natural injection of $A$ and $r$ corresponding to the natural projection onto $C$ . More precisely, there is an isomorphism of short exact sequences between the given sequence and the sequence with $B$ replaced by the direct sum of $A$ and $C$ , where the maps are the canonical inclusion and projection. Just an isomorphism of B with the direct sum is not sufficient.

The short exact sequence is called split if these statements hold.

In the above short exact sequence, where the sequence splits, it allows one to refine the first isomorphism theorem, which states that:

C ≅ B / q (A)

(i.e.,

C

isomorphic to the coimage of

r

or cokernel of

q

)

to:

B = q (A) \oplus u (C) ≅ A \oplus C

where the first isomorphism theorem is then just the projection onto $C$ .

It is a categorical generalization of the rank–nullity theorem (in the form $V ≅ ker T \oplus im T)$ in linear algebra.

Proof

$3. \Rightarrow 1.$ and $3. \Rightarrow 2.$

First, to show that 3. implies both 1. and 2., we assume .3 and take as $t$ the natural projection of the direct sum onto $A$ , and take as $u$ the natural injection of $C$ into the direct sum.

$1. \Rightarrow 3.$

To prove that 1. implies 3., first note that any member of B is in the set ( $ker t + im q$ ). This follows since for all $b$ in $B$ , $b = (b - qt (b)) + qt (b)$ ; $qt (b)$ is obviously in $im q$ , and $b - qt (b)$ is in $ker t$ , since

t (b - qt (b)) = t (b) - tqt (b) = t (b) - (tq) t (b) = t (b) - t (b) = 0.

Next, the intersection of $im q$ and $ker t$ is 0, since if there exists $a$ in $A$ such that $q (a) = b$ , and $t (b) = 0$ , then $0 = tq (a) = a$ ; and therefore, $b = 0$ .

This proves that $B$ is the direct sum of $im q$ and $ker t$ . So, for all $b$ in $B$ , $b$ can be uniquely identified by some $a$ in $A$ , $k$ in $ker t$ , such that $b = q (a) + k$ .

By exactness $ker r = im q$ . The subsequence $B ⟶ C ⟶ 0$ implies that $r$ is onto; therefore for any $c$ in $C$ there exists some $b = q (a) + k$ such that $c = r (b) = r (q (a) + k) = r (k)$ . Therefore, for any c in C, exists k in ker t such that c = r(k), and r(ker t) = C.

If $r (k) = 0$ , then $k$ is in $im q$ ; since the intersection of $im q$ and $ker t = 0$ , then $k = 0$ . Therefore the restriction of the morphism $r : ker t \to C$ is an isomorphism; and $ker t$ is isomorphic to $C$ .

Finally, $im q$ is isomorphic to $A$ due to the exactness of $0 ⟶ A ⟶ B$ ; so B is isomorphic to the direct sum of $A$ and $C$ , which proves (3).

$2. \Rightarrow 3.$

To show that 2. implies 3., we follow a similar argument. Any member of $B$ is in the set $ker r + im u$ ; since for all $b$ in $B$ , $b = (b - ur (b)) + ur (b)$ , which is in $ker r + im u$ . The intersection of $ker r$ and $im u$ is $0$ , since if $r (b) = 0$ and $u (c) = b$ , then $0 = ru (c) = c$ .

By exactness, $im q = ker r$ , and since $q$ is an injection, $im q$ is isomorphic to $A$ , so $A$ is isomorphic to $ker r$ . Since $ru$ is a bijection, $u$ is an injection, and thus $im u$ is isomorphic to $C$ . So $B$ is again the direct sum of $A$ and $C$ .

An alternative "abstract nonsense" proof of the splitting lemma may be formulated entirely in category theoretic terms.

Non-abelian groups

In the form stated here, the splitting lemma does not hold in the full category of groups, which is not an abelian category.

Partially true

It is partially true: if a short exact sequence of groups is left split or a direct sum (1. or 3.), then all of the conditions hold. For a direct sum this is clear, as one can inject from or project to the summands. For a left split sequence, the map $t \times r: B \to A \times C$ gives an isomorphism, so $B$ is a direct sum (3.), and thus inverting the isomorphism and composing with the natural injection $C \to A \times C$ gives an injection $C \to B$ splitting $r$ (2.).

However, if a short exact sequence of groups is right split (2.), then it need not be left split or a direct sum (neither 1. nor 3. follows): the problem is that the image of the right splitting need not be normal. What is true in this case is that $B$ is a semidirect product, though not in general a direct product.

Counterexample

To form a counterexample, take the smallest non-abelian group $B ≅ S 3$ , the symmetric group on three letters. Let $A$ denote the alternating subgroup, and let $C = B / A ≅ {\pm1$ }. Let $q$ and $r$ denote the inclusion map and the sign map respectively, so that

0\longrightarrow A{\stackrel {q}{\longrightarrow }}B{\stackrel {r}{\longrightarrow }}C\longrightarrow 0\,

is a short exact sequence. 3. fails, because $S 3$ is not abelian. But 2. holds: we may define $u : C \to B$ by mapping the generator to any two-cycle. Note for completeness that 1. fails: any map $t : B \to A$ must map every two-cycle to the identity because the map has to be a group homomorphism, while the order of a two-cycle is 2 which can not be divided by the order of the elements in A other than the identity element, which is 3 as $A$ is the alternating subgroup of $S 3$ , or namely the cyclic group of order 3. But every permutation is a product of two-cycles, so $t$ is the trivial map, whence $tq : A \to A$ is the trivial map, not the identity.

References

Saunders Mac Lane: Homology. Reprint of the 1975 edition, Springer Classics in Mathematics, ISBN 3-540-58662-8, p.16
Allen Hatcher: Algebraic Topology. 2002, Cambridge University Press, ISBN 0-521-79540-0, p.147

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