Hardy Spaces ($1<p<\infty$) over Lipschitz Domains (1708.01188v2)

Abstract: Let $\Gamma$ be a Lipschitz curve on the complex plane $\mathbb{C}$ and $\Omega_+$ is the domain above $\Gamma$, we define Hardy space $H^p(\Omega_+)$ as the set of holomorphic functions $F$ satisfying $\sup_{\tau>0}(\int_{\Gamma} |F(\zeta+\mathrm{i}\tau)|^p |\,\mathrm{d}\zeta|)^{\frac1p}< \infty$. We mainly focus on the case of $1<p<\infty$ in this paper, and prove that if $F(w)\in H^p(\Omega_+)$, then $F(w)$ has non-tangential boundary limit $F(\zeta)$ a.e. on $\Gamma$, and $F(w)$ is the Cauchy integral of $F(\zeta)$. We denote the conformal mapping from $\mathbb{C}+$ onto $\Omega+$ as $\Phi$, and then prove that, $ H^p(\Omega_+)$ is isomorphic to $H^p(\mathbb{C}_+)$, the classical Hardy space on upper half plane, under the mapping $T\colon F\to F(\Phi(z))\cdot (\Phi'(z))^\frac{1}{p}$, where $F\in H^p(\Omega_+)$.