Could someone help me prove the following:
Let $(\Omega,\mathscr{A},\mu)$ be a probability space. Let $f:\Omega\rightarrow\mathbb{R}$ be a non-negative measurable function. How do I prove that the funtion $N_f:p\in [1,\infty)\mapsto \Vert f\Vert_p\in[0,\infty]$ is continuous?
I already know that this function is non-decreasing. So far, I've tried the following:
Let $p\geq 1$. First suppose that $\Vert f\Vert_p<\infty$. Let $r_n<p$ be a sequence with $r_n\rightarrow p$. Since $|f|^{r_n}<\max (1, |f|^p)$, which is in $L^1(\Omega)$, and $|f|^{r_n}\rightarrow |f|^p$, then by dominated convergence, we get $\Vert f\Vert^{r_n}_{r_n}\rightarrow\Vert f\Vert_p^p$, hence $\Vert f\Vert_{r_n}=\exp\left((1/r_n)\log\Vert f\Vert_{r_n}^{r_n}\right)\rightarrow\exp\left((1/p)\log\Vert f\Vert_p^p\right)=\Vert f\Vert_p$. This shows that $N_f$ is left-continuous at p. I don't know how to prove that $N_f$ is right-continuous
If we had $\Vert f\Vert_q<\infty$ for some $q>p$, the same kind of argument would have shown that $N_f$ is continuous at $p$.
Now, suppose $\Vert f\Vert_p=\infty$. Let $r_n\rightarrow p$. Since $|f|^{r_n}\rightarrow|f|^p$, then, by Fatou-Lebesgue, $\infty=\int|f|^p\leq \liminf\int|f|^{r_n}$, hence $\liminf\Vert f\Vert_{r_n}=\infty$, which shows that $\lim\Vert f\Vert_{r_n}=\infty=\Vert f\Vert_p$.