Nodal Lengths in Shrinking Domains for Random Eigenfunctions on $\mathbb{S}^2$

Abstract: We investigate the asymptotic behavior of the nodal lines for random spherical harmonics restricted to shrinking domains, in the 2-dimensional case: i.e., the length of the zero set $\mathcal{Z}{\ell,r\ell} := \mathcal{Z}^{B_{r_{\ell}}}(T_\ell)=\text{len}({x \in \mathbb{S}^2 \cap B_{r_\ell}: T_\ell(x)=0 })$, where $B_{r_{\ell}}$ is the spherical cap of radius $r_\ell$. We show that the variance of the nodal length is logarithmic in the high energy limit; moreover, it is asymptotically fully equivalent, in the $L^2$-sense, to the "local sample trispectrum", namely, the integral on the ball of the fourth-order Hermite polynomial. This result extends and generalizes some recent findings for the full spherical case. As a consequence a Central Limit Theorem is established.