In mathematics, particularly homological algebra, the zig-zag lemma asserts the existence of a particular long exact sequence in the homology groups of certain chain complexes. The result is valid in every abelian category.
In an abelian category (such as the category of abelian groups or the category of vector spaces over a given field), let
(l{A},\partial\bullet),(l{B},\partial\bullet')
(l{C},\partial\bullet'')
0\longrightarrowl{A}l{\stackrel{\alpha}{\longrightarrow}}l{B}l{\stackrel{\beta}{\longrightarrow}}l{C}\longrightarrow0
Such a sequence is shorthand for the following commutative diagram:
commutative diagram representation of a short exact sequence of chain complexes
where the rows are exact sequences and each column is a chain complex.
The zig-zag lemma asserts that there is a collection of boundary maps
\deltan:Hn(l{C})\longrightarrowHn-1(l{A}),
that makes the following sequence exact:
long exact sequence in homology, given by the Zig-Zag Lemma
The maps
| \alpha | |
| * |
| \beta | |
| * |
| \delta | |
| n |
The maps
| \delta | |
| n |
c\inCn
Hn(l{C})
\partialn''(c)=0
| \beta | |
| n |
b\inBn
| \beta | |
| n |
(b)=c
\betan-1\partialn'(b)=\partialn''\betan(b)=\partialn''(c)=0.
By exactness,
\partialn'(b)\in\ker\betan-1=im \alphan-1.
Thus, since
| \alpha | |
| n-1 |
a\inAn-1
\alphan-1(a)=\partialn'(b)
| \alpha | |
| n-2 |
\alphan-2\partialn-1(a)=\partialn-1'\alphan-1(a)=\partialn-1'\partialn'(b)=0,
since
\partial2=0
\partialn-1(a)\in\ker\alphan-2=\{0\}
a
Hn-1(l{A})
| \delta | |
[c]=[a].
With the boundary maps defined, one can show that they are well-defined (that is, independent of the choices of c and b). The proof uses diagram chasing arguments similar to that above. Such arguments are also used to show that the sequence in homology is exact at each group.
. Allen Hatcher . 2002 . Algebraic Topology . Cambridge University Press . 0-521-79540-0 .
. James Munkres . 1993 . Elements of Algebraic Topology . Westview Press . New York . 0-201-62728-0.