Regular extension

In field theory, a branch of algebra, a field extension ${\displaystyle L/k}$ is said to be regular if k is algebraically closed in L (i.e., ${\displaystyle k=\hat{k}}$ where ${\displaystyle \hat{k}}$ is the set of elements in L algebraic over k) and L is separable over k, or equivalently, ${\displaystyle L{\otimes }_k\bar{k}}$ is an integral domain when ${\displaystyle \bar{k}}$ is the algebraic closure of ${\displaystyle k}$ (that is, to say, ${\displaystyle L,\bar{k}}$ are linearly disjoint over k).^[1][2]

• Regularity is transitive: if F/E and E/K are regular then so is F/K.^[3]
• If F/K is regular then so is E/K for any E between F and K.^[3]
• The extension L/k is regular if and only if every subfield of L finitely generated over k is regular over k.^[2]
• Any extension of an algebraically closed field is regular.^[3][4]
• An extension is regular if and only if it is separable and primary.^[5]
• A purely transcendental extension of a field is regular.

There is also a similar notion: a field extension ${\displaystyle L/k}$ is said to be self-regular if ${\displaystyle L{\otimes }_{k}L}$ is an integral domain. A self-regular extension is relatively algebraically closed in k.^[6] However, a self-regular extension is not necessarily regular.Template:Citation needed

Template:Reflist

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• M. Nagata (1985). Commutative field theory: new edition, Shokado. (Japanese) [1]
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• A. Weil, Foundations of algebraic geometry.

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