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Ring homomorphism

In mathematics, a ring homomorphism is a structure-preserving function between two rings. More explicitly, if R and S are rings, then a ring homomorphism is a function that preserves addition, multiplication and multiplicative identity; that is,

for all a, b in R.

These conditions imply that additive inverses and the additive identity are also preserved (see Group homomorphism).

If, in addition, is a bijection, then its inverse <sup>−1</sup> is also a ring homomorphism. In this case, is called a ring isomorphism, and the rings R and S are said to be isomorphic. From the standpoint of ring theory, isomorphic rings have exactly the same properties.

If R and S are s, then the corresponding notion is that of a homomorphism, defined as above except without the third condition f(1<sub>R</sub>) = 1<sub>S</sub>. A homomorphism between (unital) rings need not be a ring homomorphism.

The composition of two ring homomorphisms is a ring homomorphism. It follows that the rings form a category with ring homomorphisms as morphisms (see Category of rings). In particular, one obtains the notions of ring endomorphism, ring isomorphism, and ring automorphism.

Properties

Let be a ring homomorphism. Then, directly from these definitions, one can deduce:

  • f(0<sub>R</sub>) = 0<sub>S</sub>.
  • f(−a) = −f(a) for all a in R.
  • For any unit a in R, f(a) is a unit element such that . In particular, f induces a group homomorphism from the (multiplicative) group of units of R to the (multiplicative) group of units of S (or of im(f)).
  • The image of f, denoted im(f), is a subring of S.
  • The kernel of f, defined as , is a two-sided ideal in R. Every two-sided ideal in a ring R is the kernel of some ring homomorphism.
  • A homomorphism is injective if and only if its kernel is the zero ideal.
  • The characteristic of S divides the characteristic of R. This can sometimes be used to show that between certain rings R and S, no ring homomorphism exists.
  • If R<sub>p</sub> is the smallest subring contained in R and S<sub>p</sub> is the smallest subring contained in S, then every ring homomorphism induces a ring homomorphism .
  • If R is a division ring and S is not the zero ring, then is injective.
  • If both R and S are fields, then im(f) is a subfield of S, so S can be viewed as a field extension of R.
  • If I is an ideal of S then <sup>−1</sup>(I) is an ideal of R.
  • If R and S are commutative and P is a prime ideal of S then <sup>−1</sup>(P) is a prime ideal of R.
  • If R and S are commutative, M is a maximal ideal of S, and is surjective, then <sup>−1</sup>(M) is a maximal ideal of R.
  • If R and S are commutative and S is an integral domain, then ker(f) is a prime ideal of R.
  • If R and S are commutative, S is a field, and is surjective, then ker(f) is a maximal ideal of R.
  • If is surjective, P is prime (maximal) ideal in R and , then f(P) is prime (maximal) ideal in S.

Moreover,

  • The composition of ring homomorphisms and is a ring homomorphism .
  • For each ring R, the identity map is a ring homomorphism.
  • Therefore, the class of all rings together with ring homomorphisms forms a category, the category of rings.
  • The zero map that sends every element of R to 0 is a ring homomorphism only if S is the zero ring (the ring whose only element is zero).
  • For every ring R, there is a unique ring homomorphism . This says that the ring of integers is an initial object in the category of rings.
  • For every ring R, there is a unique ring homomorphism from R to the zero ring. This says that the zero ring is a terminal object in the category of rings.
  • As the initial object is not isomorphic to the terminal object, there is no zero object in the category of rings; in particular, the zero ring is not a zero object in the category of rings.

Examples

  • The function , defined by is a surjective ring homomorphism with kernel nZ (see Modular arithmetic).
  • The complex conjugation is a ring homomorphism (this is an example of a ring automorphism).
  • For a ring R of prime characteristic p, is a ring endomorphism called the Frobenius endomorphism.
  • If R and S are rings, the zero function from R to S is a ring homomorphism if and only if S is the zero ring (otherwise it fails to map 1<sub>R</sub> to 1<sub>S</sub>). On the other hand, the zero function is always a homomorphism.
  • If R[X] denotes the ring of all polynomials in the variable X with coefficients in the real numbers R, and C denotes the complex numbers, then the function defined by (substitute the imaginary unit i for the variable X in the polynomial p) is a surjective ring homomorphism. The kernel of f consists of all polynomials in R[X] that are divisible by .
  • If is a ring homomorphism between the rings R and S, then f induces a ring homomorphism between the matrix rings .
  • Let V be a vector space over a field k. Then the map given by is a ring homomorphism. More generally, given an abelian group M, a module structure on M over a ring R is equivalent to giving a ring homomorphism .
  • A unital algebra homomorphism between unital associative algebras over a commutative ring R is a ring homomorphism that is also R-linear.

Non-examples

  • The function defined by is not a ring homomorphism, but is a homomorphism (and endomorphism), with kernel 3Z/6Z and image 2Z/6Z (which is isomorphic to Z/3Z).
  • There is no ring homomorphism for any .
  • If R and S are rings, the inclusion that sends each r to (r,0) is a rng homomorphism, but not a ring homomorphism (if S is not the zero ring), since it does not map the multiplicative identity 1 of R to the multiplicative identity (1,1) of .

Category of rings

Endomorphisms, isomorphisms, and automorphisms

  • A ring endomorphism is a ring homomorphism from a ring to itself.
  • A ring isomorphism is a ring homomorphism having a 2-sided inverse that is also a ring homomorphism. One can prove that a ring homomorphism is an isomorphism if and only if it is bijective as a function on the underlying sets. If there exists a ring isomorphism between two rings R and S, then R and S are called isomorphic. Isomorphic rings differ only by a relabeling of elements. Example: Up to isomorphism, there are four rings of order 4. (This means that there are four pairwise non-isomorphic rings of order 4 such that every other ring of order 4 is isomorphic to one of them.) On the other hand, up to isomorphism, there are eleven s of order 4.
  • A ring automorphism is a ring isomorphism from a ring to itself.

Monomorphisms and epimorphisms

Injective ring homomorphisms are identical to monomorphisms in the category of rings: If is a monomorphism that is not injective, then it sends some r<sub>1</sub> and r<sub>2</sub> to the same element of S. Consider the two maps g<sub>1</sub> and g<sub>2</sub> from Z[x] to R that map x to r<sub>1</sub> and r<sub>2</sub>, respectively; and are identical, but since is a monomorphism this is impossible.

However, surjective ring homomorphisms are vastly different from epimorphisms in the category of rings. For example, the inclusion with the identity mapping is a ring epimorphism, but not a surjection. However, every ring epimorphism is also a strong epimorphism, the converse being true in every category.

See also

Notes

Citations

References