Lowener Theory on Analytic Universal Covering Maps

Abstract

We study Loewner chains in H0(D) without assuming univalence of each element. We prove a decomposition: every chain admits a factorization ft=F gt, where F is analytic on D(0,r) with r=t I ft'(0), and \gt\ is a classical Loewner chain of univalent functions. Under a mild regularity assumption on t ft'(0), we derive a partial differential equation that generalizes the Loewner--Kufarev equation. We then develop a Loewner theory for chains of universal covering maps. We characterize such chains in terms of domain families \t\: continuity and monotonicity of \ft\ are equivalent to kernel continuity and monotonicity of \t\. We further show that the connectivity C(t)=\#(C t) is a left-continuous nondecreasing function of t. Building on these results, we formulate a Loewner theory on Fuchsian groups and obtain evolution equations for deck transformations. As an application, we study hyperbolic metrics and establish a formula for the logarithmic derivative of the hyperbolic density along the chain. Our results provide a unified framework linking classical Loewner theory, covering maps, and the geometry of hyperbolic domains.