*Disclaimer. I posted this question [in Math.SE][1], but it haven't received enough attention.*

Let $\varphi_1$ be the first eigenfunction of the zero Dirichlet Laplacian in a planar bounded domain $\Omega$. That is,
$$
\left\{
\begin{aligned}
-\Delta \varphi_1 &= \lambda_1 \varphi_1 &&\text{in } \Omega \subset \mathbb{R}^2,\\
\varphi_1 &= 0 &&\text{on } \partial \Omega.
\end{aligned}
\right.
$$

If $\Omega$ is piece-wise smooth and has corners, and we look at the plot of $\varphi_1$, then we see that its normal derivative tends to zero near *exterior* (outward) corners, and tends to infinity near *interior* (inward) corners. 


See the plot for the standard L-shape: 
[![enter image description here][2]][2]


This fact suggests that, in a smooth domain, there should be some connection between *curvature* of the boundary at a point and the *normal derivative* of $\varphi_1$ at this point. 
That is, if the curvature is big positive, then the normal derivative is close to zero. And if the curvature is big negative, then the normal derivative is large. 

However, I was not able to find corresponding inequalities in the literature. (Although I believe that such results should be well-known.)
I would appreciate some references to such facts and related results in this direction. 

Thanks!


  [1]: https://math.stackexchange.com/questions/2518039/curvature-of-the-boundary-vs-normal-derivative-of-the-first-eigenfunction
  [2]: https://i.sstatic.net/j28X4.png