In abstract algebra, an abelian group, also called a commutative group, is a group in which the result of applying the group operation to two group elements does not depend on the order in which they are written (the axiom of commutativity). Abelian groups generalize the arithmetic of addition of integers. They are named after Niels Henrik Abel.^{[1]}
The concept of an abelian group is one of the first concepts encountered in undergraduate abstract algebra, with many other basic objects, such as a module and a vector space, being its refinements. The theory of abelian groups is generally simpler than that of their nonabelian counterparts, and finite abelian groups are very well understood. On the other hand, the theory of infinite abelian groups is an area of current research.
Contents

Definition 1

Facts 2

Notation 2.1

Multiplication table 2.2

Examples 3

Historical remarks 4

Properties 5

Finite abelian groups 6

Classification 6.1

Automorphisms 6.2

Infinite abelian groups 7

Torsion groups 7.1

Torsionfree and mixed groups 7.2

Invariants and classification 7.3

Additive groups of rings 7.4

Relation to other mathematical topics 8

A note on the typography 9

See also 10

Notes 11

References 12

External links 13
Definition
An abelian group is a set, A, together with an operation • that combines any two elements a and b to form another element denoted a • b. The symbol • is a general placeholder for a concretely given operation. To qualify as an abelian group, the set and operation, (A, •), must satisfy five requirements known as the abelian group axioms:

Closure

For all a, b in A, the result of the operation a • b is also in A.

Associativity

For all a, b and c in A, the equation (a • b) • c = a • (b • c) holds.

Identity element

There exists an element e in A, such that for all elements a in A, the equation e • a = a • e = a holds.

Inverse element

For each a in A, there exists an element b in A such that a • b = b • a = e, where e is the identity element.

Commutativity

For all a, b in A, a • b = b • a.
More compactly, an abelian group is a commutative group. A group in which the group operation is not commutative is called a "nonabelian group" or "noncommutative group".
Facts
Notation
There are two main notational conventions for abelian groups – additive and multiplicative.
Convention

Operation

Identity

Powers

Inverse

Addition

x + y

0

nx

−x

Multiplication

x ⋅ y or xy

e or 1

x^{n}

x^{−1}

Generally, the multiplicative notation is the usual notation for groups, while the additive notation is the usual notation for modules and rings. The additive notation may also be used to emphasize that a particular group is abelian, whenever both abelian and nonabelian groups are considered, some notable exceptions being nearrings and partially ordered groups, where an operation is written additively even when nonabelian.
Multiplication table
To verify that a finite group is abelian, a table (matrix) – known as a Cayley table – can be constructed in a similar fashion to a multiplication table. If the group is G = {g_{1} = e, g_{2}, ..., g_{n}} under the operation ⋅, the (i, j)th entry of this table contains the product g_{i} ⋅ g_{j}. The group is abelian if and only if this table is symmetric about the main diagonal.
This is true since if the group is abelian, then g_{i} ⋅ g_{j} = g_{j} ⋅ g_{i}. This implies that the (i, j)th entry of the table equals the (j, i)th entry, thus the table is symmetric about the main diagonal.
Examples

For the integers and the operation addition "+", denoted (Z, +), the operation + combines any two integers to form a third integer, addition is associative, zero is the additive identity, every integer n has an additive inverse, −n, and the addition operation is commutative since m + n = n + m for any two integers m and n.

Every cyclic group G is abelian, because if x, y are in G, then xy = a^{m}a^{n} a^{m + n} a^{n + m} }. Thus the integers, Z, form an abelian group under addition, as do the integers modulo n, Z/nZ.

Every ring is an abelian group with respect to its addition operation. In a commutative ring the invertible elements, or units, form an abelian multiplicative group. In particular, the real numbers are an abelian group under addition, and the nonzero real numbers are an abelian group under multiplication.

The concepts of abelian group and Zmodule agree. More specifically, every Zmodule is an abelian group with its operation of addition, and every abelian group is a module over the ring of integers Z in a unique way.
In general, matrices, even invertible matrices, do not form an abelian group under multiplication because matrix multiplication is generally not commutative. However, some groups of matrices are abelian groups under matrix multiplication – one example is the group of 2×2 rotation matrices.
Abelian groups were named after Norwegian mathematician Niels Henrik Abel by Camille Jordan because Abel found that the commutativity of the group of a polynomial implies that the roots of the polynomial can be calculated by using radicals. See Section 6.5 of Cox (2004) for more information on the historical background.
Properties
If n is a natural number and x is an element of an abelian group G written additively, then nx can be defined as x + x + ... + x (n summands) and (−n)x = −(nx). In this way, G becomes a module over the ring Z of integers. In fact, the modules over Z can be identified with the abelian groups.
Theorems about abelian groups (i.e. modules over the principal ideal domain Z) can often be generalized to theorems about modules over an arbitrary principal ideal domain. A typical example is the classification of finitely generated abelian groups which is a specialization of the structure theorem for finitely generated modules over a principal ideal domain. In the case of finitely generated abelian groups, this theorem guarantees that an abelian group splits as a direct sum of a torsion group and a free abelian group. The former may be written as a direct sum of finitely many groups of the form Z/p^{k}Z for p prime, and the latter is a direct sum of finitely many copies of Z.
If f, g : G → H are two group homomorphisms between abelian groups, then their sum f + g, defined by (f + g) (x) = f(x) + g(x), is again a homomorphism. (This is not true if H is a nonabelian group.) The set Hom(G, H) of all group homomorphisms from G to H thus turns into an abelian group in its own right.
Somewhat akin to the dimension of vector spaces, every abelian group has a rank. It is defined as the cardinality of the largest set of linearly independent elements of the group. The integers and the rational numbers have rank one, as well as every subgroup of the rationals.
Finite abelian groups
Cyclic groups of Ludwig Stickelberger and later was both simplified and generalized to finitely generated modules over a principal ideal domain, forming an important chapter of linear algebra.
Classification
The fundamental theorem of finite abelian groups states that every finite abelian group G can be expressed as the direct sum of cyclic subgroups of primepower order. This is a special case of the fundamental theorem of finitely generated abelian groups when G has zero rank.
The cyclic group Z_{mn} of order mn is isomorphic to the direct sum of Z_{m} and Z_{n} if and only if m and n are coprime. It follows that any finite abelian group G is isomorphic to a direct sum of the form

\bigoplus_{i=1}^{u}\ \mathbf{Z}_{k_i}
in either of the following canonical ways:

the numbers k_{1}, ..., k_{u} are powers of primes

k_{1} divides k_{2}, which divides k_{3}, and so on up to k_{u}.
For example, Z_{15} can be expressed as the direct sum of two cyclic subgroups of order 3 and 5: Z_{15} ≅ {0, 5, 10} ⊕ {0, 3, 6, 9, 12}. The same can be said for any abelian group of order 15, leading to the remarkable conclusion that all abelian groups of order 15 are isomorphic.
For another example, every abelian group of order 8 is isomorphic to either Z_{8} (the integers 0 to 7 under addition modulo 8), Z_{4} ⊕ Z_{2} (the odd integers 1 to 15 under multiplication modulo 16), or Z_{2} ⊕ Z_{2} ⊕ Z_{2}.
See also list of small groups for finite abelian groups of order 16 or less.
Automorphisms
One can apply the fundamental theorem to count (and sometimes determine) the automorphisms of a given finite abelian group G. To do this, one uses the fact that if G splits as a direct sum H ⊕ K of subgroups of coprime order, then Aut(H ⊕ K) ≅ Aut(H) ⊕ Aut(K).
Given this, the fundamental theorem shows that to compute the automorphism group of G it suffices to compute the automorphism groups of the Sylow psubgroups separately (that is, all direct sums of cyclic subgroups, each with order a power of p). Fix a prime p and suppose the exponents e_{i} of the cyclic factors of the Sylow psubgroup are arranged in increasing order:

e_1\leq e_2 \leq\cdots\leq e_n
for some n > 0. One needs to find the automorphisms of

\mathbf{Z}_{p^{e_1}} \oplus \cdots \oplus \mathbf{Z}_{p^{e_n}}.
One special case is when n = 1, so that there is only one cyclic primepower factor in the Sylow psubgroup P. In this case the theory of automorphisms of a finite cyclic group can be used. Another special case is when n is arbitrary but e_{i} = 1 for 1 ≤ i ≤ n. Here, one is considering P to be of the form

\mathbf{Z}_p \oplus \cdots \oplus \mathbf{Z}_p,
so elements of this subgroup can be viewed as comprising a vector space of dimension n over the finite field of p elements F_{p}. The automorphisms of this subgroup are therefore given by the invertible linear transformations, so

\mathrm{Aut}(P)\cong\mathrm{GL}(n,\mathbf{F}_p),
where GL is the appropriate general linear group. This is easily shown to have order

\mathrm{Aut}(P)=(p^n1)\cdots(p^np^{n1}).
In the most general case, where the e_{i} and n are arbitrary, the automorphism group is more difficult to determine. It is known, however, that if one defines

d_k=\mathrm{max}\{re_r = e_k^{\,}\}
and

c_k=\mathrm{min}\{re_r=e_k^{\,}\}
then one has in particular d_{k} ≥ k, c_{k} ≤ k, and

\mathrm{Aut}(P) = \prod_{k=1}^n{(p^{d_k}p^{k1})}\prod_{j=1}^n{(p^{e_j})^{nd_j}}\prod_{i=1}^n{(p^{e_i1})^{nc_i+1}}.
One can check that this yields the orders in the previous examples as special cases (see [Hillar,Rhea]).
Infinite abelian groups
Тhe simplest infinite abelian group is the infinite cyclic group Z. Any finitely generated abelian group A is isomorphic to the direct sum of r copies of Z and a finite abelian group, which in turn is decomposable into a direct sum of finitely many cyclic groups of primary orders. Even though the decomposition is not unique, the number r, called the rank of A, and the prime powers giving the orders of finite cyclic summands are uniquely determined.
By contrast, classification of general infinitely generated abelian groups is far from complete. Divisible groups, i.e. abelian groups A in which the equation nx = a admits a solution x ∈ A for any natural number n and element a of A, constitute one important class of infinite abelian groups that can be completely characterized. Every divisible group is isomorphic to a direct sum, with summands isomorphic to Q and Prüfer groups Q_{p}/Z_{p} for various prime numbers p, and the cardinality of the set of summands of each type is uniquely determined.^{[2]} Moreover, if a divisible group A is a subgroup of an abelian group G then A admits a direct complement: a subgroup C of G such that G = A ⊕ C. Thus divisible groups are injective modules in the category of abelian groups, and conversely, every injective abelian group is divisible (Baer's criterion). An abelian group without nonzero divisible subgroups is called reduced.
Two important special classes of infinite abelian groups with diametrically opposite properties are torsion groups and torsionfree groups, exemplified by the groups Q/Z (periodic) and Q (torsionfree).
Torsion groups
An abelian group is called periodic or torsion if every element has finite order. A direct sum of finite cyclic groups is periodic. Although the converse statement is not true in general, some special cases are known. The first and second Prüfer theorems state that if A is a periodic group and either it has bounded exponent, i.e. nA = 0 for some natural number n, or if A is countable and the pheights of the elements of A are finite for each p, then A is isomorphic to a direct sum of finite cyclic groups.^{[3]} The cardinality of the set of direct summands isomorphic to Z/p^{m}Z in such a decomposition is an invariant of A. These theorems were later subsumed in the Kulikov criterion. In a different direction, Helmut Ulm found an extension of the second Prüfer theorem to countable abelian pgroups with elements of infinite height: those groups are completely classified by means of their Ulm invariants.
Torsionfree and mixed groups
An abelian group is called torsionfree if every nonzero element has infinite order. Several classes of torsionfree abelian groups have been studied extensively:
An abelian group that is neither periodic nor torsionfree is called mixed. If A is an abelian group and T(A) is its torsion subgroup then the factor group A/T(A) is torsionfree. However, in general the torsion subgroup is not a direct summand of A, so A is not isomorphic to T(A) ⊕ A/T(A). Thus the theory of mixed groups involves more than simply combining the results about periodic and torsionfree groups.
Invariants and classification
One of the most basic invariants of an infinite abelian group A is its rank: the cardinality of the maximal linearly independent subset of A. Abelian groups of rank 0 are precisely the periodic groups, while torsionfree abelian groups of rank 1 are necessarily subgroups of Q and can be completely described. More generally, a torsionfree abelian group of finite rank r is a subgroup of Q^{r}. On the other hand, the group of padic integers Z_{p} is a torsionfree abelian group of infinite Zrank and the groups Z_{p}^{n} with different n are nonisomorphic, so this invariant does not even fully capture properties of some familiar groups.
The classification theorems for finitely generated, divisible, countable periodic, and rank 1 torsionfree abelian groups explained above were all obtained before 1950 and form a foundation of the classification of more general infinite abelian groups. Important technical tools used in classification of infinite abelian groups are pure and basic subgroups. Introduction of various invariants of torsionfree abelian groups has been one avenue of further progress. See the books by Irving Kaplansky, László Fuchs, Phillip Griffith, and David Arnold, as well as the proceedings of the conferences on Abelian Group Theory published in Lecture Notes in Mathematics for more recent results.
Additive groups of rings
The additive group of a ring is an abelian group, but not all abelian groups are additive groups of rings (with nontrivial multiplication). Some important topics in this area of study are:

Tensor product

Corner's results on countable torsionfree groups

Shelah's work to remove cardinality restrictions.
Relation to other mathematical topics
Many large abelian groups possess a natural topology, which turns them into topological groups.
The collection of all abelian groups, together with the homomorphisms between them, forms the category Ab, the prototype of an abelian category.
Nearly all wellknown algebraic structures other than Boolean algebras are undecidable. Hence it is surprising that Tarski's student Szmielew (1955) proved that the first order theory of abelian groups, unlike its nonabelian counterpart, is decidable. This decidability, plus the fundamental theorem of finite abelian groups described above, highlight some of the successes in abelian group theory, but there are still many areas of current research:

Amongst torsionfree abelian groups of finite rank, only the finitely generated case and the rank 1 case are well understood;

There are many unsolved problems in the theory of infiniterank torsionfree abelian groups;

While countable torsion abelian groups are well understood through simple presentations and Ulm invariants, the case of countable mixed groups is much less mature.

Many mild extensions of the first order theory of abelian groups are known to be undecidable.

Finite abelian groups remain a topic of research in computational group theory.
Moreover, abelian groups of infinite order lead, quite surprisingly, to deep questions about the set theory commonly assumed to underlie all of mathematics. Take the Whitehead problem: are all Whitehead groups of infinite order also free abelian groups? In the 1970s, Saharon Shelah proved that the Whitehead problem is:
A note on the typography
Among mathematical adjectives derived from the proper name of a mathematician, the word "abelian" is rare in that it is often spelled with a lowercase a, rather than an uppercase A, indicating how ubiquitous the concept is in modern mathematics.^{[4]}
See also
Notes

^ Jacobson (2009), p. 41

^ For example, Q/Z ≅ ∑_{p} Q_{p}/Z_{p}.

^ Countability assumption in the second Prüfer theorem cannot be removed: the torsion subgroup of the direct product of the cyclic groups Z/p^{m}Z for all natural m is not a direct sum of cyclic groups.

^ Abel Prize Awarded: The Mathematicians' Nobel
References
External links
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