Hausdorff dimension of pinned distance sets and the $L^2$-method

Abstract: We prove that for any $E\subset{\Bbb R}^2$, $\dim_{\mathcal{H}}(E)>1$, there exists $x\in E$ such that the Hausdorff dimension of the pinned distance set $$\Delta_x(E)={|x-y|: y \in E}$$ is no less than $\min\left{\frac{4}{3}\dim_{\mathcal{H}}(E)-\frac{2}{3}, 1\right}$. This answers a question recently raised by Guth, Iosevich, Ou and Wang, as well as improves results of Keleti and Shmerkin. (This version is already published on Proceeding AMS so I would like to leave it unchanged. However the statement in the abstract, which is the second part of Theorem 1.1, should be weakened a bit to: for any $\epsilon>0$ there exists $x\in E$ such that the Hausdorff dimension of $\Delta_x(E)$ is at least $\min\left{\frac{4}{3}\dim_{\mathcal{H}}(E)-\frac{2}{3}-\epsilon, 1\right}$, and it implies the Hausdorff dimension of the distance set, $\Delta(E)={|x-y|:x,y\in E}$, is at least $\min\left{\frac{4}{3}\dim_{\mathcal{H}}(E)-\frac{2}{3}, 1\right}$. There is no problem in the proof and the first part of Theorem 1.1. I apologize for being sloppy and would like to thank Yumeng Ou for pointing it out.)