Multiplicatively closed set

In abstract algebra, a multiplicatively closed set (or multiplicative set) is a subset S of a ring R such that the following two conditions hold:^[1]^[2]

$1\in S$ {\displaystyle 1\in S},
$xy\in S$ {\displaystyle xy\in S} for all $x,y\in S$ {\displaystyle x,y\in S}.

In other words, S is closed under taking finite products, including the empty product 1.^[3] Equivalently, a multiplicative set is a submonoid of the multiplicative monoid of a ring.

Multiplicative sets are important especially in commutative algebra, where they are used to build localizations of commutative rings.

A subset S of a ring R is called saturated if it is closed under taking divisors: i.e., whenever a product xy is in S, the elements x and y are in S too.

Examples

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Examples of multiplicative sets include:

the set-theoretic complement of a prime ideal in a commutative ring;
the set {1, x, x², x³, ...}, where x is an element of a ring;
the set of units of a ring;
the set of non-zero-divisors in a ring;
1 + I for an ideal I;
the Jordan–Pólya numbers, the multiplicative closure of the factorials.

Properties

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An ideal P of a commutative ring R is prime if and only if its complement R \ P is multiplicatively closed.
An ideal P of a commutative ring R that is maximal with respect to being disjoint from a multiplicative set S is a prime ideal (Krull). In fact, if ideal I is disjoint from S, there exists prime ideal P such that $R\setminus S\supseteq P\supseteq I$ {\displaystyle R\setminus S\supseteq P\supseteq I}.
A subset S is both saturated and multiplicatively closed if and only if S is the complement of a union of prime ideals.^[4] In particular, the complement of a prime ideal is both saturated and multiplicatively closed.
The intersection of a family of multiplicative sets is a multiplicative set.
The intersection of a family of saturated sets is saturated.