Intersection Number, Length, and Systole on Compact Hyperbolic Surfaces (2306.09249v1)

Abstract: Let $\mathcal{M}g$ be the moduli space of compact hyperbolic surfaces of genus $g$. Given $X\in \mathcal{M}_g$, let $\ell_X(\gamma_1)$ and $i(\gamma_1,\gamma_2)$ denote the length and geometric intersection number of a pair of closed geodesics on $X$, and let $$ I(X):=\sup \limits{\gamma_1,\gamma_2} \frac{i(\gamma_1,\gamma_2)}{\ell_X(\gamma_1)\ell_X(\gamma_2)}. $$ We refer to $I(X)$ as the {\em interaction strength} on $X$, since it controls the best upper bound on $i(\gamma_1,\gamma_2)$ in terms of $\ell_X(\gamma_1)\ell_X(\gamma_2)$. It is easy to see that $I(X)<\infty$ and $I(X) \to \infty$ as $X \to \infty$ in $\mathcal{M}g$. Our main result describes the exact asymptotic behaviour of $I(X)$ on $\mathcal{M}_g$: we show $$ I(X) \sim \frac{1}{2\operatorname{sys}(X)\log(\frac{1}{\operatorname{sys}(X)})}, $$ as $X \to \infty$ in $\mathcal{M}_g$. Here $\operatorname{sys}(X):=\inf \limits{\gamma} \ell_X(\gamma)$ denotes the {\em systole} of $X$. We obtain a similar result for finite volume hyperbolic surfaces, provided we restrict attention to closed geodesics in a fixed compact subset of $X$. We also show: $$ \min \limits_{X \in \mathcal{M}_g} I(X) \asymp \frac{1}{(\log g)^2}; $$ in particular, the minimum of $I(X)$ over $\mathcal{M}_g$ tends to zero as $g \to \infty$.