A subgroup ${\displaystyle N}$  of a group ${\displaystyle G}$  is called a normal subgroup of ${\displaystyle G}$  if it is invariant under conjugation; that is, the conjugation of an element of ${\displaystyle N}$  by an element of ${\displaystyle G}$  is always in ${\displaystyle N.}$ ^[3] The usual notation for this relation is ${\displaystyle N\triangleleft G.}$ 

Equivalent conditions edit

For any subgroup ${\displaystyle N}$  of ${\displaystyle G,}$  the following conditions are equivalent to ${\displaystyle N}$  being a normal subgroup of ${\displaystyle G.}$  Therefore, any one of them may be taken as the definition.

• The image of conjugation of ${\displaystyle N}$  by any element of ${\displaystyle G}$  is a subset of ${\displaystyle N,}$ ^[4] i.e., ${\displaystyle gNg^{-1}\subseteq N}$  for all ${\displaystyle g\in G}$ .
• The image of conjugation of ${\displaystyle N}$  by any element of ${\displaystyle G}$  is equal to ${\displaystyle N,}$ ^[4] i.e., ${\displaystyle gNg^{-1}=N}$  for all ${\displaystyle g\in G}$ .
• For all ${\displaystyle g\in G,}$  the left and right cosets ${\displaystyle gN}$  and ${\displaystyle Ng}$  are equal.^[4]
• The sets of left and right cosets of ${\displaystyle N}$  in ${\displaystyle G}$  coincide.^[4]
• Multiplication in ${\displaystyle G}$  preserves the equivalence relation "is in the same left coset as". That is, for every ${\displaystyle g,g',h,h'\in G}$  satisfying ${\displaystyle gN=g'N}$  and ${\displaystyle hN=h'N}$ , we have ${\displaystyle (gh)N=(g'h')N.}$ 
• There exists a group on the set of left cosets of ${\displaystyle N}$  where multiplication of any two left cosets ${\displaystyle gN}$  and ${\displaystyle hN}$  yields the left coset ${\displaystyle (gh)N}$ . (This group is called the quotient group of ${\displaystyle G}$  modulo ${\displaystyle N}$ , denoted ${\displaystyle G/N}$ .)
• ${\displaystyle N}$  is a union of conjugacy classes of ${\displaystyle G.}$ ^[2]
• ${\displaystyle N}$  is preserved by the inner automorphisms of ${\displaystyle G.}$ ^[5]
• There is some group homomorphism ${\displaystyle G\to H}$  whose kernel is ${\displaystyle N.}$ ^[2]
• There exists a group homomorphism ${\displaystyle \phi :G\to H}$  whose fibers form a group where the identity element is ${\displaystyle N}$  and multiplication of any two fibers ${\displaystyle \phi ^{-1}(h_{1})}$  and ${\displaystyle \phi ^{-1}(h_{2})}$  yields the fiber ${\displaystyle \phi ^{-1}(h_{1}h_{2})}$ . (This group is the same group ${\displaystyle G/N}$  mentioned above.)
• There is some congruence relation on ${\displaystyle G}$  for which the equivalence class of the identity element is ${\displaystyle N}$ .
• For all ${\displaystyle n\in N}$  and ${\displaystyle g\in G,}$  the commutator ${\displaystyle [n,g]=n^{-1}g^{-1}ng}$  is in ${\displaystyle N.}$ ^{[citation needed]}
• Any two elements commute modulo the normal subgroup membership relation. That is, for all ${\displaystyle g,h\in G,}$  ${\displaystyle gh\in N}$  if and only if ${\displaystyle hg\in N.}$ ^{[citation needed]}

For any group ${\displaystyle G,}$  the trivial subgroup ${\displaystyle \{e\}}$  consisting of just the identity element of ${\displaystyle G}$  is always a normal subgroup of ${\displaystyle G.}$  Likewise, ${\displaystyle G}$  itself is always a normal subgroup of ${\displaystyle G.}$  (If these are the only normal subgroups, then ${\displaystyle G}$  is said to be simple.)^[6] 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 ${\displaystyle [G,G].}$ ^[7][8] More generally, since conjugation is an isomorphism, any characteristic subgroup is a normal subgroup.^[9]

If ${\displaystyle G}$  is an abelian group then every subgroup ${\displaystyle N}$  of ${\displaystyle G}$  is normal, because ${\displaystyle gN=\{gn\}_{n\in N}=\{ng\}_{n\in N}=Ng.}$  More generally, for any group ${\displaystyle G}$ , every subgroup of the center ${\displaystyle Z(G)}$  of ${\displaystyle G}$  is normal in ${\displaystyle G}$ . (In the special case that ${\displaystyle G}$  is abelian, the center is all of ${\displaystyle G}$ , 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.^[10]

A concrete example of a normal subgroup is the subgroup ${\displaystyle N=\{(1),(123),(132)\}}$  of the symmetric group ${\displaystyle S_{3},}$  consisting of the identity and both three-cycles. In particular, one can check that every coset of ${\displaystyle N}$  is either equal to ${\displaystyle N}$  itself or is equal to ${\displaystyle (12)N=\{(12),(23),(13)\}.}$  On the other hand, the subgroup ${\displaystyle H=\{(1),(12)\}}$  is not normal in ${\displaystyle S_{3}}$  since ${\displaystyle (123)H=\{(123),(13)\}\neq \{(123),(23)\}=H(123).}$ ^[11] This illustrates the general fact that any subgroup ${\displaystyle H\leq G}$  of index two is normal.

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

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.^[12]

The translation group is a normal subgroup of the Euclidean group in any dimension.^[13] 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 ${\displaystyle H}$  is a normal subgroup of ${\displaystyle G,}$  and ${\displaystyle K}$  is a subgroup of ${\displaystyle G}$  containing ${\displaystyle H,}$  then ${\displaystyle H}$  is a normal subgroup of ${\displaystyle K.}$ ^[14]
• 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.^[15] However, a characteristic subgroup of a normal subgroup is normal.^[16] A group in which normality is transitive is called a T-group.^[17]
• The two groups ${\displaystyle G}$  and ${\displaystyle H}$  are normal subgroups of their direct product ${\displaystyle G\times H.}$ 
• If the group ${\displaystyle G}$  is a semidirect product ${\displaystyle G=N\rtimes H,}$  then ${\displaystyle N}$  is normal in ${\displaystyle G,}$  though ${\displaystyle H}$  need not be normal in ${\displaystyle G.}$ 
• If ${\displaystyle M}$  and ${\displaystyle N}$  are normal subgroups of an additive group ${\displaystyle G}$  such that ${\displaystyle G=M+N}$  and ${\displaystyle M\cap N=\{0\}}$ , then ${\displaystyle G=M\oplus N.}$ ^[18]
• Normality is preserved under surjective homomorphisms;^[19] that is, if ${\displaystyle G\to H}$  is a surjective group homomorphism and ${\displaystyle N}$  is normal in ${\displaystyle G,}$  then the image ${\displaystyle f(N)}$  is normal in ${\displaystyle H.}$ 
• Normality is preserved by taking inverse images;^[19] that is, if ${\displaystyle G\to H}$  is a group homomorphism and ${\displaystyle N}$  is normal in ${\displaystyle H,}$  then the inverse image ${\displaystyle f^{-1}(N)}$  is normal in ${\displaystyle G.}$ 
• Normality is preserved on taking direct products;^[20] that is, if ${\displaystyle N_{1}\triangleleft G_{1}}$  and ${\displaystyle N_{2}\triangleleft G_{2},}$  then ${\displaystyle N_{1}\times N_{2}\;\triangleleft \;G_{1}\times G_{2}.}$ 
• Every subgroup of index 2 is normal. More generally, a subgroup, ${\displaystyle H,}$  of finite index, ${\displaystyle n,}$  in ${\displaystyle G}$  contains a subgroup, ${\displaystyle K,}$  normal in ${\displaystyle G}$  and of index dividing ${\displaystyle n!}$  called the normal core. In particular, if ${\displaystyle p}$  is the smallest prime dividing the order of ${\displaystyle G,}$  then every subgroup of index ${\displaystyle p}$  is normal.^[21]
• The fact that normal subgroups of ${\displaystyle G}$  are precisely the kernels of group homomorphisms defined on ${\displaystyle G}$  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,^[22] 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.

Lattice of normal subgroups edit

Given two normal subgroups, ${\displaystyle N}$  and ${\displaystyle M,}$  of ${\displaystyle G,}$  their intersection ${\displaystyle N\cap M}$ and their product ${\displaystyle NM=\{nm:n\in N\;{\text{ and }}\;m\in M\}}$  are also normal subgroups of ${\displaystyle G.}$ 

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

The lattice is complete and modular.^[20]

If ${\displaystyle N}$  is a normal subgroup, we can define a multiplication on cosets as follows:

With this operation, the set of cosets is itself a group, called the quotient group and denoted with ${\displaystyle G/N.}$  There is a natural homomorphism, ${\displaystyle f:G\to G/N,}$  given by ${\displaystyle f(a)=aN.}$  This homomorphism maps ${\displaystyle N}$  into the identity element of ${\displaystyle G/N,}$  which is the coset ${\displaystyle eN=N,}$ ^[23] that is, ${\displaystyle \ker(f)=N.}$ 

In general, a group homomorphism, ${\displaystyle f:G\to H}$  sends subgroups of ${\displaystyle G}$  to subgroups of ${\displaystyle H.}$  Also, the preimage of any subgroup of ${\displaystyle H}$  is a subgroup of ${\displaystyle G.}$  We call the preimage of the trivial group ${\displaystyle \{e\}}$  in ${\displaystyle H}$  the kernel of the homomorphism and denote it by ${\displaystyle \ker f.}$  As it turns out, the kernel is always normal and the image of ${\displaystyle G,f(G),}$  is always isomorphic to ${\displaystyle G/\ker f}$  (the first isomorphism theorem).^[24] In fact, this correspondence is a bijection between the set of all quotient groups of ${\displaystyle G,G/N,}$  and the set of all homomorphic images of ${\displaystyle G}$  (up to isomorphism).^[25] It is also easy to see that the kernel of the quotient map, ${\displaystyle f:G\to G/N,}$  is ${\displaystyle N}$  itself, so the normal subgroups are precisely the kernels of homomorphisms with domain ${\displaystyle G.}$ ^[26]

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

• Weisstein, Eric W. "normal subgroup". 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?