Contents

Definition

Let $R$ be a commutative ring, let $\mathrm{Reg}(R)$ be the monoid of regular elements in $R$, let $\neg \mathrm{Reg}(R)$ be the complement of $\mathrm{Reg}(R)$, the set of zero divisors in $R$, and let $I_{\neg \mathrm{Reg}(R)}$ be the two-sided ideal generated by $\neg \mathrm{Reg}(R)$. A commutative ring is non-trivial if $0 \neq 1$.

Since every element of the ideal generated by the set of zero divisors is equal to zero, and the integral domain is a non-trivial ring, which means that there is at least one zero divisor, it follows that zero is a zero divisor and if $a \cdot b = 0$, then $a = 0$ or $b = 0$. It then follows that every integral domain is a reduced ring.

The ring of fractions of every integral domain is a field, the field of fractions.

The ring of formal power series of an integral domain is a local integral domain.

While every ring homomorphism between fields is an injection, it is not the case that every ring homomorphism between integral domains is an injection. The ring homomorphism which takes a local integral domain to its quotient by its Jacobson radical is an injection if and only if the local integral domain is already a field.

 Examples

• GCD domain
• Bezout domain
• unique factorization domain
• principal ideal domain
• Euclidean domain
• Dedekind domain
• field
• valuation ring

In constructive mathematics

in constructive mathematics, there are different inequivalent ways to define an integral domain. The above definition is sometimes called a ring without zero divisors or a weak integral domain. Stronger notions include:

Rings without zero divisors and discrete integral domains are both definable in coherent logic. However, Heyting integral domains can only be defined in first-order logic.

Generalizations

Sometimes, one may want the trivial ring to be an integral domain, resulting in the notion of possibly trivial integral domain. In LombardiQuitté2010, the authors define an integral domain to be a possibly trivial integral domain.

In principle, one could just as easily consider a commutative rig or commutative semiring $R$. In that case, however, only the definition involving the cancellative property extends to rigs and semirings. Furthermore, we should add the additional requirement that addition in $R$ is cancellable (that is, addition by any element is injective), to make the analogue of the previous paragraph correct. Since these could also be done for general domains to turn them into what could be called domain rigs and domain semirings, these could be called commutative domain rigs or commutative domain semirings.

Related concepts

• domain (ring theory)

• commutative ring

• approximate integral domain

• possibly trivial integral domain

• field, field of fractions

• torsion-free module

• integral monoid

• difference protoring

• reduced ring

commutative ring	reduced ring	integral domain
local ring	reduced local ring	local integral domain
Artinian ring	semisimple ring	field
Weil ring	field	field

Reference

• Henri Lombardi, Claude Quitté (2010): Commutative algebra: Constructive methods (Finite projective modules) Translated by Tania K. Roblo, Springer (2015) (doi:10.1007/978-94-017-9944-7, pdf)

See also

• Wikipedia, Integral domain

On limits of integral domains among commutative rings:

• Michael Barr, John Kennison, Robert Raphael, Limit closures of classes of commutative rings, Theory Appl. Categories 30 (2015) 229–304 [tac:30-08, pdf]