Integral extension implies surjective map on spectra: Difference between revisions

This article gives the statement, and possibly proof, of a fact about how a property of a homomorphism of commutative unital rings, forces a property for the induced map on spectra
View other facts about induced maps on spectra

Name

This result is sometimes termed lying over, and is a precursor to the going up theorem.

Statement

Suppose ${\displaystyle S}$ is an integral extension of a ring ${\displaystyle R}$, in other words ${\displaystyle f:R\to S}$ is an injective homomorphism of commutative unital rings with the property that every element of ${\displaystyle S}$ is integral over the image of ${\displaystyle R}$. Then, the following are true.

The map:

${\displaystyle f^{*}:Spec(S)\to Spec(R)}$

from the spectrum of ${\displaystyle S}$ to that of ${\displaystyle R}$, that sends a prime ideal of ${\displaystyle S}$ to its contraction in ${\displaystyle R}$, is surjective. In other words, every prime ideal of ${\displaystyle R}$ occurs as the contraction of a prime ideal of ${\displaystyle S}$.

This result is sometimes termed the lying over theorem.

Note that injectivity of ${\displaystyle f}$ is crucial for surjectivity of the map on spectra; this is analogous to the fact that surjective ring homomorphisms induce injective maps on spectra.

Related facts

• Integral extension implies inverse image of max-spectrum is max-spectrum
• Going up theorem: The going up theorem is a somewhat stronger version of this result, and also follows as a corollary of this result.

Proof

The goal is to prove that starting with a prime ideal ${\displaystyle P}$ of ${\displaystyle R}$, we can find a prime ideal ${\displaystyle Q}$ of ${\displaystyle S}$ such that ${\displaystyle f^{-1}(Q)=P}$.

We localize ${\displaystyle R}$ at ${\displaystyle P}$, and localize ${\displaystyle S}$ at the image of ${\displaystyle U=R\setminus P}$ to get ${\displaystyle S'}$. Then ${\displaystyle R_{P}}$ is a local ring with unique maximal ideal ${\displaystyle P'=PR_{P}}$, and ${\displaystyle f}$ induces a map ${\displaystyle R_{P}\to S'=S[U^{-1}]}$.

We thus have an inclusion ${\displaystyle f:R_{P}\to S'}$. Consider the image ${\displaystyle P'S'}$. This is an ideal of ${\displaystyle S'}$. If ${\displaystyle P'S'}$ is a proper ideal, it is contained in some maximal ideal ${\displaystyle M}$, and the contraction of that maximal ideal to ${\displaystyle R_{P}}$ is precisely ${\displaystyle P'}$. Contracting back along the localization, we find a prime ideal of ${\displaystyle S'}$, whose contraction is exactly ${\displaystyle P}$. (we are using the fact that contracting a maximal ideal of ${\displaystyle S'}$ yields a prime, though not necessarily maximal, ideal of ${\displaystyle S}$).

Thus, the main goal is to show that ${\displaystyle P'S'\neq S'}$ (this is where we need to use integrality). The idea is to construct a ${\displaystyle R}$-subalgebra of ${\displaystyle S'}$, called ${\displaystyle S''}$, that is finite over ${\displaystyle R_{P}}$, and use Nakayama's lemma to derive a contradiction. Here are the steps:

• Since ${\displaystyle S}$ is integral over ${\displaystyle R}$, ${\displaystyle S'}$ is integral over ${\displaystyle R_{P}}$
• If ${\displaystyle P'S'=S'}$, then the element ${\displaystyle 1\in S'}$ can be written as a ${\displaystyle P'}$-linear combination of finitely many elements from ${\displaystyle S'}$
• Let ${\displaystyle S''}$ be the ${\displaystyle R_{P}}$-subalgebra generated by these finitely many elements. Then ${\displaystyle S''}$ is finitely generated and integral over ${\displaystyle R_{P}}$, hence it is finitely generated as a module over ${\displaystyle R_{P}}$. For full proof, refer: finitely generated and integral implies finite
• We thus have ${\displaystyle P'S''=S''}$ (since ${\displaystyle 1\in P'S''}$). Since ${\displaystyle P'}$ is the Jacobson radical of ${\displaystyle R_{P}}$, Nakayama's lemma tells us that ${\displaystyle S''=0}$, yielding a contradiction.