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The questions asks to show that if $A$ is a ring and $I, J_{1}, J_{2}$ ideals of $A$, and $P$ is a prime ideal, then $I \subset J_{1} \cup J_{2} \cup P$ implies $I \subset J_{1}$ or $J_{2}$ or $P$.

I've been trying to work with the contrapositive and use that $I \subset J_{1} \cup J_{2}$ implies $I \subset J_{1}$ or $I \subset J_{2}$ in order to ascertain an element of $I$ that's not in the union, but I had no luck. Can anyone please shed some light? Thanks a lot in advance!

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Prime avoidance – Georges Elencwajg Sep 20 '12 at 17:21

As commented by Georges Elencwajg, this is a special case of the prime avoidance Lemma.

Here is a proof for your situation.

Assume the claim is wrong.

First we deal with the special case that $I$ is a subset of the union $I_1 \cup I_2$ of any two of the three ideals $J_1, J_2$ and $P$. Then by our assumption there is an $a\in I\setminus I_2$ and a $b\in I\setminus I_1$. Since $I\subset I_1\cup I_2$, $a\in I_1$ and $b\in I_2$ and from $a + b\in I$ we get w.l.o.g. $a + b\in I_1$. Thus $b = (a + b) - a\in I_1$, contradiction.

It remains to consider the case that there exist elements $a\in I\setminus (P \cup J_1)$, $b\in I\setminus (P\cup J_2)$ and $p\in I\setminus (J_1\cup J_2)$. Then $a\in J_1$, $b\in J_2$ and $p\in P$. The element $x = ab + p$ is in $I$ and therefore in at least one of the ideals $J_1$, $J_2$ or $P$.

If $x\in J_1$, then $p = x - ab\in J_1$ (note that from $a\in J_1$ and the ideal property of $J_1$ it follows that $ab\in J_1$). Contradiction.

In the same way, $x\in J_2$ yields a contradiction.

If $x\in P$, then $ab = x - p\in P$. From the primality of $P$ we get $a\in P$ or $b\in P$, which is again a contradiction.

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