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Possible Duplicate:
The set of all nilpotent element is an ideal of R

Given a commutative ring $R$ and two nilpotent elements $r$, $s$ there exists an $n \in \mathbb{N}$ such that

$ (r+s)^n = 0.$

I want to prove that in order to show that the nilpotent elements of a commutative ring are closed under addition (to show that the nilpotent elements form an ideal within a commutative ring). Is that a good way to do it? I'm a little stuck.

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    Yes, that will do it. Hint: binomial theorem.2012-04-16

1 Answers 1

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By the binomial theorem, $(r+s)^n = \sum_{k=0}^n \binom{n}{k} r^k s^{n-k}.$ If $r^a = s^b = 0$ choose $n = a+b$. Then for each $k=0,1,\ldots,n$ either $k \geq a$ or $n-k \geq b$ so $r^k = 0$ or $s^{n-k} = 0$.