Normal subgroup

Template:Short description Template:Redirect-distinguish Template:Group theory sidebar In abstract algebra, a normal subgroup (also known as an invariant subgroup or self-conjugate subgroup)Template:Sfn is a subgroup that is invariant under conjugation by members of the group of which it is a part. In other words, a subgroup <math>N</math> of the group <math>G</math> is normal in <math>G</math> if and only if <math>gng^{-1} \in N</math> for all <math>g \in G</math> and <math>n \in N</math>. The usual notation for this relation is <math>N \triangleleft G</math>.

Normal subgroups are important because they (and only they) can be used to construct quotient groups of the given group. Furthermore, the normal subgroups of <math>G</math> are precisely the kernels of group homomorphisms with domain <math>G</math>, which means that they can be used to internally classify those homomorphisms.

Évariste Galois was the first to realize the importance of the existence of normal subgroups.Template:Sfn

A subgroup <math>N</math> of a group <math>G</math> is called a normal subgroup of <math>G</math> if it is invariant under conjugation; that is, the conjugation of an element of <math>N</math> by an element of <math>G</math> is always in <math>N</math>.Template:Sfn The usual notation for this relation is <math>N \triangleleft G</math>.

For any subgroup <math>N</math> of <math>G</math>, the following conditions are equivalent to <math>N</math> being a normal subgroup of <math>G</math>. Therefore, any one of them may be taken as the definition.

• The image of conjugation of <math>N</math> by any element of <math>G</math> is a subset of <math>N</math>,Template:Sfn i.e., <math>gNg^{-1}\subseteq N</math> for all <math>g\in G</math>.
• The image of conjugation of <math>N</math> by any element of <math>G</math> is equal to <math>N,</math>Template:Sfn i.e., <math>gNg^{-1}= N</math> for all <math>g\in G</math>.
• For all <math>g \in G</math>, the left and right cosets <math>gN</math> and <math>Ng</math> are equal.Template:Sfn
• The sets of left and right cosets of <math>N</math> in <math>G</math> coincide.Template:Sfn
• Multiplication in <math>G</math> preserves the equivalence relation "is in the same left coset as". That is, for every <math>g,g',h,h'\in G</math> satisfying <math>g N = g' N</math> and <math>h N = h' N</math>, we have <math>(g h) N = (g' h') N</math>.
• There exists a group on the set of left cosets of <math>N</math> where multiplication of any two left cosets <math>gN</math> and <math>hN</math> yields the left coset <math>(gh)N</math> (this group is called the quotient group of <math>G</math> modulo <math>N</math>, denoted <math>G/N</math>).
• <math>N</math> is a union of conjugacy classes of <math>G</math>.Template:Sfn
• <math>N</math> is preserved by the inner automorphisms of <math>G</math>.Template:Sfn
• There is some group homomorphism <math>G \to H</math> whose kernel is <math>N</math>.Template:Sfn
• There exists a group homomorphism <math>\phi:G \to H</math> whose fibers form a group where the identity element is <math>N</math> and multiplication of any two fibers <math>\phi^{-1}(h_1)</math> and <math>\phi^{-1}(h_2)</math> yields the fiber <math>\phi^{-1}(h_1 h_2)</math> (this group is the same group <math>G/N</math> mentioned above).
• There is some congruence relation on <math>G</math> for which the equivalence class of the identity element is <math>N</math>.
• For all <math>n\in N</math> and <math>g\in G</math>. the commutator <math>[n,g] = n^{-1} g^{-1} n g</math> is in <math>N</math>.Template:Cn
• Any two elements commute modulo the normal subgroup membership relation. That is, for all <math>g, h \in G</math>, <math>g h \in N</math> if and only if <math>h g \in N</math>.Template:Cn

For any group <math>G</math>, the trivial subgroup <math>\{ e \}</math> consisting of only the identity element of <math>G</math> is always a normal subgroup of <math>G</math>. Likewise, <math>G</math> itself is always a normal subgroup of <math>G</math> (if these are the only normal subgroups, then <math>G</math> is said to be simple).Template:Sfn Other named normal subgroups of an arbitrary group include the center of the group (the set of elements that commute with all other elements) and the commutator subgroup <math>[G,G]</math>.Template:SfnTemplate:Sfn More generally, since conjugation is an isomorphism, any characteristic subgroup is a normal subgroup.Template:Sfn

If <math>G</math> is an abelian group then every subgroup <math>N</math> of <math>G</math> is normal, because <math>gN = \{gn\}_{n\in N} = \{ng\}_{n\in N} = Ng</math>. More generally, for any group <math>G</math>, every subgroup of the center <math>Z(G)</math> of <math>G</math> is normal in <math>G</math> (in the special case that <math>G</math> is abelian, the center is all of <math>G</math>, hence the fact that all subgroups of an abelian group are normal). A group that is not abelian but for which every subgroup is normal is called a Hamiltonian group.Template:Sfn

A concrete example of a normal subgroup is the subgroup <math>N = \{(1), (123), (132)\}</math> of the symmetric group <math>S_3</math>, consisting of the identity and both three-cycles. In particular, one can check that every coset of <math>N</math> is either equal to <math>N</math> itself or is equal to <math>(12)N = \{ (12), (23), (13)\}</math>. On the other hand, the subgroup <math>H = \{(1), (12)\}</math> is not normal in <math>S_3</math> since <math>(123)H = \{(123), (13) \} \neq \{(123), (23) \} = H(123)</math>.Template:Sfn This illustrates the general fact that any subgroup <math>H \leq G</math> of index two is normal.

As an example of a normal subgroup within a matrix group, consider the general linear group <math>\mathrm{GL}_n(\mathbf{R})</math> of all invertible <math>n\times n</math> matrices with real entries under the operation of matrix multiplication and its subgroup <math>\mathrm{SL}_n(\mathbf{R})</math> of all <math>n\times n</math> matrices of determinant 1 (the special linear group). To see why the subgroup <math>\mathrm{SL}_n(\mathbf{R})</math> is normal in <math>\mathrm{GL}_n(\mathbf{R})</math>, consider any matrix <math>X</math> in <math>\mathrm{SL}_n(\mathbf{R})</math> and any invertible matrix <math>A</math>. Then using the two important identities <math>\det(AB)=\det(A)\det(B)</math> and <math>\det(A^{-1})=\det(A)^{-1}</math>, one has that <math>\det(AXA^{-1}) = \det(A) \det(X) \det(A)^{-1} = \det(X) = 1</math>, and so <math>AXA^{-1} \in \mathrm{SL}_n(\mathbf{R})</math> as well. This means <math>\mathrm{SL}_n(\mathbf{R})</math> is closed under conjugation in <math>\mathrm{GL}_n(\mathbf{R})</math>, so it is a normal subgroup.Template:Efn

In the Rubik's Cube group, the subgroups consisting of operations which only affect the orientations of either the corner pieces or the edge pieces are normal.Template:Sfn

The translation group is a normal subgroup of the Euclidean group in any dimension.Template:Sfn This means: applying a rigid transformation, followed by a translation and then the inverse rigid transformation, has the same effect as a single translation. By contrast, the subgroup of all rotations about the origin is not a normal subgroup of the Euclidean group, as long as the dimension is at least 2: first translating, then rotating about the origin, and then translating back will typically not fix the origin and will therefore not have the same effect as a single rotation about the origin.

• If <math>H</math> is a normal subgroup of <math>G</math>, and <math>K</math> is a subgroup of <math>G</math> containing <math>H</math>, then <math>H</math> is a normal subgroup of <math>K</math>.Template:Sfn
• A normal subgroup of a normal subgroup of a group need not be normal in the group. That is, normality is not a transitive relation. The smallest group exhibiting this phenomenon is the dihedral group of order 8.Template:Sfn However, a characteristic subgroup of a normal subgroup is normal.Template:Sfn A group in which normality is transitive is called a T-group.Template:Sfn
• The two groups <math>G</math> and <math>H</math> are normal subgroups of their direct product <math>G \times H</math>.
• If the group <math>G</math> is a semidirect product <math>G = N \rtimes H</math>, then <math>N</math> is normal in <math>G</math>, though <math>H</math> need not be normal in <math>G</math>.
• If <math>M</math> and <math>N</math> are normal subgroups of an additive group <math>G</math> such that <math>G = M + N</math> and <math>M \cap N = \{0\}</math>, then <math>G = M \oplus N</math>.Template:Sfn
• Normality is preserved under surjective homomorphisms;Template:Sfn that is, if <math>G \to H</math> is a surjective group homomorphism and <math>N</math> is normal in <math>G</math>, then the image <math>f(N)</math> is normal in <math>H</math>.
• Normality is preserved by taking inverse images;Template:Sfn that is, if <math>G \to H</math> is a group homomorphism and <math>N</math> is normal in <math>H</math>, then the inverse image <math>f^{-1}(N)</math> is normal in <math>G</math>.
• Normality is preserved on taking direct products;Template:Sfn that is, if <math>N_1 \triangleleft G_1</math> and <math>N_2 \triangleleft G_2</math>, then <math>N_1 \times N_2\; \triangleleft \;G_1 \times G_2</math>.
• Every subgroup of index 2 is normal. More generally, a subgroup, <math>H</math>, of finite index, <math>n</math>, in <math>G</math> contains a subgroup, <math>K,</math> normal in <math>G</math> and of index dividing <math>n!</math> called the normal core. In particular, if <math>p</math> is the smallest prime dividing the order of <math>G</math>, then every subgroup of index <math>p</math> is normal.Template:Sfn
• The fact that normal subgroups of <math>G</math> are precisely the kernels of group homomorphisms defined on <math>G</math> accounts for some of the importance of normal subgroups; they are a way to internally classify all homomorphisms defined on a group. For example, a non-identity finite group is simple if and only if it is isomorphic to all of its non-identity homomorphic images,Template:Sfn a finite group is perfect if and only if it has no normal subgroups of prime index, and a group is imperfect if and only if the derived subgroup is not supplemented by any proper normal subgroup.

Given two normal subgroups, <math>N</math> and <math>M</math>, of <math>G</math>, their intersection <math>N\cap M</math> and their product <math>N M = \{n m : n \in N\; \text{ and }\; m \in M \}</math> are also normal subgroups of <math>G</math>.

The normal subgroups of <math>G</math> form a lattice under subset inclusion with least element, <math>\{ e \}</math>, and greatest element, <math>G</math>. The meet of two normal subgroups, <math>N</math> and <math>M</math>, in this lattice is their intersection and the join is their product.

The lattice is complete and modular.Template:Sfn

If <math>N</math> is a normal subgroup, we can define a multiplication on cosets as follows: <math display="block">\left(a_1 N\right) \left(a_2 N\right) := \left(a_1 a_2\right) N</math> This relation defines a mapping <math>G/N\times G/N \to G/N</math>. To show that this mapping is well-defined, one needs to prove that the choice of representative elements <math>a_1, a_2</math> does not affect the result. To this end, consider some other representative elements <math>a_1'\in a_1 N, a_2' \in a_2 N</math>. Then there are <math>n_1, n_2\in N</math> such that <math>a_1' = a_1 n_1, a_2' = a_2 n_2</math>. It follows that <math display="block">a_1' a_2' N = a_1 n_1 a_2 n_2 N =a_1 a_2 n_1' n_2 N=a_1 a_2 N</math>where we also used the fact that <math>N</math> is a Template:Em subgroup, and therefore there is <math>n_1'\in N</math> such that <math>n_1 a_2 = a_2 n_1'</math>. This proves that this product is a well-defined mapping between cosets.

With this operation, the set of cosets is itself a group, called the quotient group and denoted with <math>G/N.</math> There is a natural homomorphism, <math>f : G \to G/N</math>, given by <math>f(a) = a N</math>. This homomorphism maps <math>N</math> into the identity element of <math>G/N</math>, which is the coset <math>e N = N</math>,Template:Sfn that is, <math>\ker(f) = N</math>.

In general, a group homomorphism, <math>f : G \to H</math> sends subgroups of <math>G</math> to subgroups of <math>H</math>. Also, the preimage of any subgroup of <math>H</math> is a subgroup of <math>G</math>. We call the preimage of the trivial group <math>\{ e \}</math> in <math>H</math> the kernel of the homomorphism and denote it by <math>\ker f</math>. As it turns out, the kernel is always normal and the image of <math>G, f(G)</math>, is always isomorphic to <math>G / \ker f</math> (the first isomorphism theorem).Template:Sfn In fact, this correspondence is a bijection between the set of all quotient groups of <math>G</math>, <math>G/N</math>, and the set of all homomorphic images of <math>G</math> (up to isomorphism).Template:Sfn It is also easy to see that the kernel of the quotient map, <math>f : G \to G/N</math>, is <math>N</math> itself, so the normal subgroups are precisely the kernels of homomorphisms with domain <math>G</math>.Template:Sfn

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• Normalizer
• Conjugate closure
• Normal core

• Malnormal subgroup
• Contranormal subgroup
• Abnormal subgroup
• Self-normalizing subgroup

• Characteristic subgroup
• Fully characteristic subgroup

• Subnormal subgroup
• Ascendant subgroup
• Descendant subgroup
• Quasinormal subgroup
• Seminormal subgroup
• Conjugate permutable subgroup
• Modular subgroup
• Pronormal subgroup
• Paranormal subgroup
• Polynormal subgroup
• C-normal subgroup

• Ideal (ring theory)
• Semigroup ideal

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Template:Refend

• I. N. Herstein, Topics in algebra. Second edition. Xerox College Publishing, Lexington, Mass.-Toronto, Ont., 1975. xi+388 pp.

• Template:MathWorld
• Normal subgroup in Springer's Encyclopedia of Mathematics
• Robert Ash: Group Fundamentals in Abstract Algebra. The Basic Graduate Year
• Timothy Gowers, Normal subgroups and quotient groups
• John Baez, What's a Normal Subgroup?