If $f_k \to f$ a.e. and the $L^p$ norms converge, then $f_k \to f$ in $L^p$
This is a theorem by Riesz.
Observe that $$|f_k - f|^p \leq 2^p (|f_k|^p + |f|^p),$$
Now we can apply Fatou's lemma to $$2^p (|f_k|^p + |f|^p) - |f_k - f|^p \geq 0.$$
If you look well enough you will notice that this implies that
$$\limsup_{k \to \infty} \int |f_k - f|^p \, d\mu = 0.$$
Hence you can conclude the same for the normal limit.
Consider $g_k = 2^p(|f_k|^p + |f|^p) - |f_k - f|^p$.
Since $g_k \geq 0$ (why?), and $g_k \to 2^{p+1}|f|^p$ a.e., we can apply Fatou's Lemma: $$\int \liminf g_k \leq \liminf \int g_k$$ so that $$\int 2^{p+1}|f|^p \leq \liminf \left(\int 2^p |f_k|^p + \int 2^p |f|^p - \int |f_k - f|^p \right),$$ and I'll let you take it from here.