Is the space $C_0^{k}(\Omega)$ a Montel space?

Question

I asked this question in the MathStackExchange, but I think I'm not get any answer.

I'm trying to find a reference for the following result:

Theorem: Let $\Omega$ be a open subset of $\mathbb{R}^{d}$ and $k\geq 0$. Then $C_0^{k}(\Omega)$ it is (not) a (semi-)Montel space.

I tried to find in the classical references, Trèves, Horváth, but without success. The best result I found, it is the the Exercise 34.4 in Trèves book, which ensures that $C^k(\Omega)$ it is not a Montel space. Can we conclude from this exercise the Theorem above?

I'm trying to prove the following result, but I don't know if this result is valid.

A proof of this result would also be welcome.

Answer 1

In the following I write $C^k_K(\Omega)$ for the space of all $C^k(\Omega)$ functions having support included in $K$, equipped with its "natural" norm $\|\cdot\|_{K,k}$ (uniform norm on $K$ of all derivatives up to the order $k$). I also fix a countable exhaustion $(K_n)_n$ of $\Omega$. I assume that $C^k_0(\Omega)$ is equipped with the inductive limit topology $\tau$ which satisfies in particular :

$(i)$ For all $n$, the embedding $C^k_{K_n}(\Omega)\hookrightarrow C^k_0(\Omega)$ is continuous

$(ii)$ The trace topology of $\tau$ on $C^k_{K_n}(\Omega)$ is precisely the one of $\|\cdot\|_{K_n,k}$.

In this setting, I think that $C^k_0(\Omega)$ is not Montel, for finite $k$.

Indeed : $C^k_{K_n}(\Omega)$ is a normed space of infinite dimension : it cannot be Montel (this argument fails when $k=\infty$ obviously), for instance the unit ball of $C^k_{K_n}(\Omega)$ is bounded and not compact. Because of $(i)$, this unit ball is also bounded in $C^k_0(\Omega)$. But because of $(ii)$, it cannot be compact for the $\tau$ toplogy, otherwise this would imply compactness in $C^k_{K_n}(\Omega)$.