Bohr Radius and Landau-type Theorems for Harmonic Mappings with Boundary Functions in Lebesgue Spaces

Abstract

This paper investigates the geometric and analytical properties of harmonic mappings f in the unit disk D induced by boundary functions F belonging to the Lebesgue spaces Lp(T) for 1 p ∞. We first establish a sharp Bohr-type inequality for the class of bounded harmonic mappings. Specifically, we prove that for a fixed analytic part |a0|= aM, the majorant series Mf(r) satisfies Mf(r) M for r (1-a)/(1-a+4/π), and demonstrate that this radius is best possible. This result is subsequently extended to harmonic mappings with Lp boundary functions, where we determine the sharp Bohr radius rp = 1/(2Cq+1), with Cq being a constant depending on the conjugate exponent q. Furthermore, the paper provides improved Landau-type theorems for these mappings. Under standard normalization, we derive explicit expressions for the radius of univalence r0 and the radius of the inscribed schlicht disk R0. The sharpness of these constants is discussed through the construction of extremal functions related to the Poisson kernel.