$R$ is commutative, $I$,$J$ are ideals, $I+J=R$, then $IJ=I\cap J$ [duplicate]

abstract-algebra ring-theory

Solution 1:

There are $i\in I, j\in J$ such that $i+j=1$. Then, for all $a\in I\cap J$, $$a=a1=a(i+j)=ai+aj\in JI+IJ=IJ.$$

Solution 2:

$I \cap J = (I \cap J) \cdot R \\ = (I \cap J) \cdot (I + J) \\ = (I \cap J) \cdot I + (I \cap J) \cdot J \\ \subseteq IJ + IJ \\ = IJ.$

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