Let $\Omega$ an open and bounded domain in $R^n$ . Let $u \in W^{1,p} (\Omega) \cap L^{\infty}(\Omega)$ $(2 \leq p < \infty)$ . Let $B \subset \subset \Omega$ a open ball and consider $u_1$ the restriction of $u$ on $B$. Then we have $u_1 \in W^{1,p} (B) \cap L^{\infty}(B)$. Let $T : W^{1,p} (B) \rightarrow L^{p}(\partial B) $ the trace operator. Can I say that $T(u_1) \in L^{\infty}(\partial B)$ ? Intuitively this is true .. But I dont know how to proof or counter example... Someone can give me a help? I am not good with the trace operator...
thanks in advance
Let $\phi_n\in C^\infty(B)$ be a sequence satisfying: $\phi_n\to u_1$ in $W^{1,p}(B)$ and $\|\phi_n\|_\infty\le M$ for all $n$, where $M$ is a positive constant (see here).
Note that $\phi_n\to u_1$ in $W^{1,p}(B)$, therefore, $(\phi_n-M)^+\to (u_1-M)^+$ in $W^{1,p}(B)$.
By one hand, $T((\phi_n-M)^+)=0$ for all $n$. On the other hand, once $(\phi_n-M)^+\to (u_1-M)^+$ in $W^{1,p}(B)$, we have that $T((\phi_n-M)^+)\to T((u_1-M)^+)$, thus $T((u_1-M)^+)=0$.
The last paragraph does implies that $$\inf\{\alpha\in\mathbb{R}:\ T((u_1-\alpha)^+)=0\}<\infty.$$
To conclude, use this post.