In mathematics, specifically abstract algebra, the isomorphism theorems are three theorems that describe the relationship between quotients, homomorphisms, and subobjects. Versions of the theorems exist for groups, rings, vector spaces, modules, Lie algebras, and various other algebraic structures. In universal algebra, the isomorphism theorems can be generalized to the context of algebras and congruences.
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The isomorphism theorems were formulated in some generality for homomorphisms of modules by Emmy Noether in her paper Abstrakter Aufbau der Idealtheorie in algebraischen Zahl- und Funktionenkörpern which was published in 1927 in Mathematische Annalen. Less general versions of these theorems can be found in work of Richard Dedekind and previous papers by Noether.
Three years later, B.L. van der Waerden published his influential Algebra, the first abstract algebra textbook that took the now-traditional groups-rings-fields approach to the subject. Van der Waerden credited lectures by Noether on group theory and Emil Artin on algebra, as well as a seminar conducted by Artin, Wilhelm Blaschke, Otto Schreier, and van der Waerden himself on ideals as the main references. The three isomorphism theorems, called homomorphism theorem, and two laws of isomorphism when applied to groups, appear explicitly.
We first state the three isomorphism theorems in the context of groups. Note that some sources switch the numbering of the second and third theorems.[1] Sometimes, the lattice theorem is referred to as the fourth isomorphism theorem or the correspondence theorem.
Let G and H be groups, and let φ: G → H be a homomorphism. Then:
In particular, if φ is surjective then H is isomorphic to G / ker(φ).
Let G be a group. Let S be a subgroup of G, and let N be a normal subgroup of G. Then:
Technically, it is not necessary for N to be a normal subgroup, as long as S is a subgroup of the normalizer of N. In this case, the intersection S ∩ N is not a normal subgroup of G, but it is still a normal subgroup of S.
Let G be a group. Let N and K be normal subgroups of G, with
Then
The first isomorphism theorem follows from the category theoretical fact that the category of groups is (normal epi, mono)-factorizable; in other words, the normal epimorphisms and the monomorphisms form a factorization system for the category. This is captured in the commutative diagram in the margin, which shows the objects and morphisms whose existence can be deduced from the morphism f: G→H. The diagram shows that every morphism in the category of groups has a kernel in the category theoretical sense; the arbitrary morphism f factors into , where ι is a monomorphism and π is an epimorphism (in a conormal category, all epimorphisms are normal). This is represented in the diagram by an object and a monomorphism (kernels are always monomorphisms), which complete the short exact sequence running from the lower left to the upper right of the diagram. The use of the exact sequence convention saves us from having to draw the zero morphisms from to H and .
If the sequence is right split (i. e., there is a morphism σ that maps to a π-preimage of itself), then G is the semidirect product of the normal subgroup and the subgroup . If it is left split (i. e., there exists some such that ), then it must also be right split, and is a direct product decomposition of G. In general, the existence of a right split does not imply the existence of a left split; but in an abelian category (such as the abelian groups), left splits and right splits are equivalent by the splitting lemma, and a right split is sufficient to produce a direct sum decomposition . In an abelian category, all monomorphisms are also normal, and the diagram may be extended by a second short exact sequence .
In the second isomorphism theorem, the product SN is the join of S and N in the lattice of subgroups of G, while the intersection S ∩ N is the meet.
The third isomorphism theorem is generalized by the nine lemma to abelian categories and more general maps between objects. It is sometimes informally called the "freshman theorem", because "even a freshman could figure it out: just cancel out the Ks!"
The statements of the theorems for rings are similar, with the notion of a normal subgroup replaced by the notion of an ideal.
Let R and S be rings, and let φ: R → S be a ring homomorphism. Then:
In particular, if φ is surjective then S is isomorphic to R / ker(φ).
Let R be a ring. Let S be a subring of R, and let I be an ideal of R. Then:
Let R be a ring. Let A and B be ideals of R, with
Then
The statements of the isomorphism theorems for modules are particularly simple, since it is possible to form a quotient module from any submodule. The isomorphism theorems for vector spaces and abelian groups are special cases of these. For vector spaces, all of these theorems follow from the rank-nullity theorem.
For all of the following theorems, the word “module” will mean “R-module”, where R is some fixed ring.
Let M and N be modules, and let φ: M → N be a homomorphism. Then:
In particular, if φ is surjective then N is isomorphic to M / ker(φ).
Let M be a module, and let S and T be submodules of M. Then:
Let M be a module. Let S and T be submodules of M, with
Then
To generalise this to universal algebra, normal subgroups need to be replaced by congruences.
Briefly, if is an algebra, a congruence on is an equivalence relation on which is a subalgebra when considered as a subset of (the latter with the coordinate-wise operation structure). One can make the set of equivalence classes into an algebra of the same type by defining the operations via representatives; this will be well-defined since is a subalgebra of .
If and are algebras, and is a homomorphism , then the equivalence relation on defined by if and only if is a congruence on , and the algebra is isomorphic to the image of , which is a subalgebra of .
Given an algebra , a subalgebra of , and a congruence on , we let be the subset of determined by all congruence classes that contain an element of , and we let be the intersection of (considered as a subset of ) with . Then is a subalgebra of , is a congruence on , and the algebra is isomorphic to the algebra .
Let be an algebra, and let and be two congruence relations on , with contained in . Then determines a congruence on defined by if and only if and are equivalent modulo (where represents the -equivalence class of ), and is isomorphic to .