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Let $M$ be left $R$-module and $A$ ,$B$ are two submodule of $M$ such that $A\times B\cong M$.

Is there submodule $C$ such that $A+C=M$ and $A\cap C=0$?

All my attempts proving the $A$ has a complement in $M$ but it seems to be wrong, but can not find any counter example(s) for it.

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    What do you mean by $A \times B$? I have never seen this notation before. Do you mean $A+B$? Or $A \oplus B$?2012-10-05
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    @Aaron $A\times B$ means the product of two module. some references use the symbol "$\oplus$" for product of two module but I use this symbol"$\times$".2012-10-05
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    Ahh, okay. Finite products are the same as finite direct sums, which is why people generally use direct sum when there are only finitely many modules. But with submodules, there are sums that are not direct, and I was assuming this was some kind of product that was not direct (which confused me).2012-10-05

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This is already false for finite $\mathbb{Z}$-modules, i.e. abelian groups.

Let $M$ be $\mathbb{Z}_4 \times \mathbb{Z}_2$, $A$ be $\langle 2 \rangle \times \langle 0 \rangle$, and $B$ be $\langle 1 \rangle \times \langle 0 \rangle$. Then $M \cong A \times B$, but $A$ is not complemented in $M$.

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    It is probably worth saying why there is no complement. Here is a quick proof. If there were a complement, then we would have a projection map $p:M\to A$ such that elements of $A$ were left fixed. However, this is impossible because $2p(\langle 1\rangle\times \langle 0 \rangle)=0$ (since the subgroup generated by $\langle 2\rangle\times \langle 0\rangle$ is isomorphic to $\mathbb Z_2$)2012-10-05