Improved Degree Bounds for Hyperbolicity of Surfaces and Curve Complements
Lei Hou, Dinh Tuan Huynh, Joël Merker, Song-Yan Xie
Abstract
This paper establishes new degree bounds for Kobayashi hyperbolicity in dimension two. Our main results are: - A very generic surface in $\mathbb{P}^3$ of degree at least $17$ is Kobayashi hyperbolic. - The complement of a generic curve in $\mathbb{P}^2$ of degree at least $12$ is Kobayashi hyperbolic. These bounds improve the long-standing records in the field. For surfaces, the threshold is lowered from Păun's degree $18$ to degree $17$; for complements, it is lowered from Rousseau's degree $14$ to degree $12$. For complements, we prove a stronger, quantitative version of hyperbolicity via a Second Main Theorem in Nevanlinna theory. Specifically, for every generic smooth curve $\mathcal{C} \subset \mathbb{P}^2$ of degree $d \geqslant 12$ and any nonconstant entire holomorphic curve $f \colon \mathbb{C} \to \mathbb{P}^2$, we establish the following inequality: \[ T_f(r) \leqslant C_d \, N_f^{[1]}(r, \mathcal{C}) + o\big(T_f(r)\big) \quad \parallel, \] where $T_f(r)$ is the Nevanlinna characteristic function, $N_f^{[1]}(r, \mathcal{C})$ denotes the $1$-truncated counting function, and $C_d$ is an explicit constant depending only on $d$. The notation ``$\parallel$'' indicates that the estimate holds for all $r>1$ outside a set of finite Lebesgue measure.