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I know that if $V$ is a finite-dimensional vector space and $T$ is a linear operator on $V$, then $T$ is a direct sum of a nilpotent operator and an invertible operator.

My question is: Is there an infinite-dimensional vector space $V$ over a field $\mathbb{F}$ such that every linear operator $T$ on $V$ can be written as a direct sum of a nilpotent linear operator and an invertible linear operator?

I mean "There are subspaces such that $V=M\oplus N$ where $T$ is invertible on $M$ and $T$ is nilpotent on $N$"?

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    @BillCook: Yes!$I$will add it to my question. Thank you for point ir out.2012-02-09

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No (at least assuming AC). Let $V$ be an infinite dimensional vector space, let $B$ be a basis for $V$, let $b\in B$, and let $f:B\to B\setminus\{b\}$ be a bijection. Let $T:V\to V$ be the unique linear transformation such that $T|_B=f$. Since $T$ is injective, its restriction to every subspace is injective, so the only subspace on which $T$ is nilpotent is $\{0\}$. But $T$ is not invertible, because $b$ is not in its range.

All that was needed for this example is that there exists an injective but not surjective linear operator on $V$. Similarly, a surjective but not injective operator has no nilpotent summand on a nontrivial subspace, and is not invertible.