Continuous extension of of ring \(Q\)-homeomorphisms in metric spaces (Q2901703)

Suppose that \((X, d, \mu)\) and \(\left(X^{\prime}, d^{\prime}, \mu^{\prime}\right)\) are metric spaces with locally finite measures \(\mu\) and \(\mu^{\prime}\), respectively, and let \(G\) and \(G^{\prime}\) be domains of finite Hausdorff dimension \(\alpha\) resp. \(\alpha^{\prime}\). It is proved that a ring \(Q\)-homeomorphism \(f:G\rightarrow G^{\prime}\) can be continuously extended to a boundary point \(x_0\in \partial G\) if \(X\) is \(\alpha\)-regular at \(x_0\), \(G\) is locally linearly connected and satisfies some logarithmic double-measure condition, \(\overline{G^{\prime}}\) is compact, \(\partial G^{\prime}\) is strongly accessible and a given real-valued function \(Q\) has finite mean oscillation at the point \(x_0\). Another result states that the limit sets \(C(x_1, f)\) and \(C(x_2, f)\) are disjoint for every ring \(Q\)-homeomorphism \(f:G\rightarrow G^{\prime}\) with \(Q\in L^1(G)\) provided that \(G\) is locally connected at \(x_1\) and \(x_2\), \(x_1\neq x_2\), and \(G^{\prime}\) has weakly flat boundary.