On the Dirichlet problem for the Schrödinger equation with boundary value in BMO space (2006.05248v2)

Abstract: Let $(X,d,\mu)$ be a metric measure space satisfying a $Q$-doubling condition, $Q>1$, and an $L^2$-Poincar\'{e} inequality. Let $\mathscr{L}=\mathcal{L}+V$ be a Schr\"odinger operator on $X$, where $\mathcal{L}$ is a non-negative operator generalized by a Dirichlet form, and $V$ is a non-negative Muckenhoupt weight that satisfies a reverse H\"older condition $RH_q$ for some $q\ge (Q+1)/2$. We show that a solution to $(\mathscr{L}-\partial_t^2)u=0$ on $X\times \mathbb{R}+$ satisfies the Carleson condition, $$\sup{B(x_B,r_B)}\frac{1}{\mu(B(x_B,r_B))} \int_{0}^{r_B} \int_{B(x_B,r_B)} |t\nabla u(x,t)|^2 \frac{\mathrm{d}\mu\mathrm{d} t}{t}<\infty,$$ if and only if, $u$ can be represented as the Poisson integral of the Schr\"odinger operator $\mathscr{L}$ with trace in the BMO space associated with $\mathscr{L}$.