In mathematics, specifically in the field of group theory, a divisible group is an abelian group in which every element can, in some sense, be divided by positive integers, or more accurately, every element is an nth multiple for each positive integer n. Divisible groups are important in understanding the structure of abelian groups, especially because they are the injective abelian groups.
An abelian group
(G,+)
n
g\inG
y\inG
ny=g
n
nG=G
y
n
g
nG\supseteqG
nG\subseteqG
G
G
An abelian group is
p
p
g\inG
y\inG
py=g
p
pG=G
Q
Q
Q/Z
Z[1/p]/Z
Q/Z
Z[pinfty]
C*
A
T
HomZ-Mod(A,T)
A
Let G be a divisible group. Then the torsion subgroup Tor(G) of G is divisible. Since a divisible group is an injective module, Tor(G) is a direct summand of G. So
G=Tor(G) ⊕ G/Tor(G).
As a quotient of a divisible group, G/Tor(G) is divisible. Moreover, it is torsion-free. Thus, it is a vector space over Q and so there exists a set I such that
G/Tor(G)=oplusiQ=Q(I).
The structure of the torsion subgroup is harder to determine, but one can show that for all prime numbers p there exists
Ip
(Tor(G))p=
oplus | |
i\inIp |
Z[pinfty]=Z[pinfty]
(Ip) | |
,
where
(Tor(G))p
Thus, if P is the set of prime numbers,
G=\left(opluspZ[pinfty]
(Ip) | |
\right) ⊕ Q(I).
The cardinalities of the sets I and Ip for p ∈ P are uniquely determined by the group G.
See main article: Injective envelope. As stated above, any abelian group A can be uniquely embedded in a divisible group D as an essential subgroup. This divisible group D is the injective envelope of A, and this concept is the injective hull in the category of abelian groups.
An abelian group is said to be reduced if its only divisible subgroup is . Every abelian group is the direct sum of a divisible subgroup and a reduced subgroup. In fact, there is a unique largest divisible subgroup of any group, and this divisible subgroup is a direct summand.[6] This is a special feature of hereditary rings like the integers Z: the direct sum of injective modules is injective because the ring is Noetherian, and the quotients of injectives are injective because the ring is hereditary, so any submodule generated by injective modules is injective. The converse is a result of : if every module has a unique maximal injective submodule, then the ring is hereditary.
A complete classification of countable reduced periodic abelian groups is given by Ulm's theorem.
Several distinct definitions generalize divisible groups to divisible modules. The following definitions have been used in the literature to define a divisible module M over a ring R:
The last two conditions are "restricted versions" of the Baer's criterion for injective modules. Since injective left modules extend homomorphisms from all left ideals to R, injective modules are clearly divisible in sense 2 and 3.
If R is additionally a domain then all three definitions coincide. If R is a principal left ideal domain, then divisible modules coincide with injective modules. Thus in the case of the ring of integers Z, which is a principal ideal domain, a Z-module (which is exactly an abelian group) is divisible if and only if it is injective.
If R is a commutative domain, then the injective R modules coincide with the divisible R modules if and only if R is a Dedekind domain.
. The theory of groups . Marshall Hall (mathematician) . New York . Macmillan . 1959 . Chapter 13.3.
. Infinite Abelian Groups. Irving Kaplansky . University of Michigan Press . 1965 .
. Infinite Abelian Groups Vol 1. László Fuchs . Academic Press . 1970 .
. Algebra, Second Edition . Serge Lang . Serge Lang . Menlo Park, California . Addison-Wesley . 1984 .