Semi-local ring

In mathematics, a semi-local ring is a ring for which R/J(R) is a semisimple ring, where J(R) is the Jacobson radical of R.

The above definition is satisfied if R has a finite number of maximal right ideals (and finite number of maximal left ideals). When R is a commutative ring, the converse implication is also true, and so the definition of semi-local for commutative rings is often taken to be "having finitely many maximal ideals".

Some literature refers to a commutative semi-local ring in general as a quasi-semi-local ring, using semi-local ring to refer to a Noetherian ring with finitely many maximal ideals.

A semi-local ring is thus more general than a local ring, which has only one maximal (right/left/two-sided) ideal.

Examples

 * Any right or left Artinian ring, any serial ring, and any semiperfect ring is semi-local.
 * The quotient $$\mathbb{Z}/m\mathbb{Z}$$ is a semi-local ring. In particular, if $$m$$ is a prime power, then $$\mathbb{Z}/m\mathbb{Z}$$ is a local ring.
 * A finite direct sum of fields $$\bigoplus_{i=1}^n{F_i}$$ is a semi-local ring.
 * In the case of commutative rings with unity, this example is prototypical in the following sense: the Chinese remainder theorem shows that for a semi-local commutative ring R with unit and maximal ideals m1, ..., mn
 * $$R/\bigcap_{i=1}^n m_i\cong\bigoplus_{i=1}^n R/m_i\,$$.
 * (The map is the natural projection). The right hand side is a direct sum of fields. Here we note that ∩i mi=J(R), and we see that R/J(R) is indeed a semisimple ring.


 * The classical ring of quotients for any commutative Noetherian ring is a semilocal ring.
 * The endomorphism ring of an Artinian module is a semilocal ring.
 * Semi-local rings occur for example in algebraic geometry when a (commutative) ring R is localized with respect to the multiplicatively closed subset S = ∩ (R \ pi), where the pi are finitely many prime ideals.