In mathematics, in the area of commutative algebra, tight closure is an operation defined on ideals in positive characteristic. It was introduced by Melvin Hochster and Craig Huneke (1988, 1990).

Let $R$ be a commutative noetherian ring containing a field of characteristic $p>0$ . Hence $p$ is a prime number.

Let $I$ be an ideal of $R$ . The tight closure of $I$ , denoted by ${\displaystyle I^{*))$ , is another ideal of $R$ containing $I$ . The ideal ${\displaystyle I^{*))$ is defined as follows.

{\displaystyle z\in I^{*))

if and only if there exists a

c\in R

, where

c

is not contained in any minimal prime ideal of

R

, such that

{\displaystyle cz^{p^{e))\in I^{[p^{e}]))

for all

e\gg 0

. If

R

is reduced, then one can instead consider all

e>0

.

Here ${\displaystyle I^{[p^{e}]))$ is used to denote the ideal of $R$ generated by the ${\displaystyle p^{e))$ 'th powers of elements of $I$ , called the $e$ th Frobenius power of $I$ .

An ideal is called tightly closed if ${\displaystyle I=I^{*))$ . A ring in which all ideals are tightly closed is called weakly $F$ -regular (for Frobenius regular). A previous major open question in tight closure is whether the operation of tight closure commutes with localization, and so there is the additional notion of $F$ -regular, which says that all ideals of the ring are still tightly closed in localizations of the ring.

Brenner & Monsky (2010) found a counterexample to the localization property of tight closure. However, there is still an open question of whether every weakly $F$ -regular ring is $F$ -regular. That is, if every ideal in a ring is tightly closed, is it true that every ideal in every localization of that ring is also tightly closed?

References