product of injective modules is injective

Proposition. Let $R$ be a ring and $\{Q_{i}\}_{i\in I}$ a family of injective $R$ -modules. Then the product

$Q=\prod_{i\in I}\ Q_{i}$

is injective.

Proof. Let $B$ be an arbitrary $R$ -module, $A\subseteq B$ a submodule and $f:A\to Q$ a homomorphism. It is enough to show that $f$ can be extended to $B$ . For $i\in I$ denote by $\pi_{i}:Q\to Q_{i}$ the projection. Since $Q_{i}$ is injective for any $i$ , then the homomorphism $\pi_{i}\circ f:A\to Q_{i}$ can be extended to $f^{\prime}_{i}:B\to Q_{i}$ . Then we have

$f^{\prime}:B\to Q;$

$f^{\prime}(b)=\big{(}f^{\prime}_{i}(b)\big{)}_{i\in I}.$

It is easy to check, that if $a\in A$ , then $f^{\prime}(a)=f(a)$ , so $f^{\prime}$ is an extension of $f$ . Thus $Q$ is injective. $\square$

Remark. Unfortunetly direct sum of injective modules need not be injective. Indeed, there is a theorem which states that direct sums of injective modules are injective if and only if ring $R$ is Noetherian. Note that the proof presented above cannot be used for direct sums, because $f^{\prime}(b)$ need not be an element of the direct sum, more precisely, it is possible that $f^{\prime}_{i}(b)\neq 0$ for infinetly many $i\in I$ . Nevertheless products are always injective.

Title	product of injective modules is injective
Canonical name	ProductOfInjectiveModulesIsInjective
Date of creation	2013-03-22 18:50:17
Last modified on	2013-03-22 18:50:17
Owner	joking (16130)
Last modified by	joking (16130)
Numerical id	5
Author	joking (16130)
Entry type	Theorem
Classification	msc 16D50