Saved in:
Bibliographic Details
Main Authors: David, Chantal, Devin, Lucile, Waxman, Ezra
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.15597
Tags: Add Tag
No Tags, Be the first to tag this record!
Table of Contents:
  • We study the low-lying zeros of a family of $L$-functions attached to the CM elliptic curve $E_d \;:\; y^2 = x^3 - dx$, for each odd and square-free integer $d$. Specifically, upon writing the $L$-function of $E_d$ as $L(s-\frac12, ξ_d)$ for the appropriate Grössencharakter $ξ_d$ of conductor $\mathfrak{f}_d$, we consider the collection $\mathcal{F}_d$ of $L$-functions attached to $ξ_{d,k}$, $k \geq 1$, where for each integer $k$, $ξ_{d, k}$ denotes the primitive character inducing $ξ_d^k$. We observe that $25\%$ of the $L$-functions in $\mathcal{F}_d$ have negative root number. $\mathcal{F}_d$ is thus not one of the essentially homogeneous families of the Universality Conjecture of Sarnak, Shin and Templier, with unitary, symplectic or orthogonal (odd or even) symmetry type. By computing the one-level density in the family of $L$-functions in $\mathcal{F}_{d}$ with conductor at most $K^2 \mathrm N (\mathfrak{f}_d)$, we find that $\mathcal{F}_d$ naturally decomposes into subfamilies: more specifically, a collection of symplectic ($L(s, ξ_{d,k})$ for $k \equiv α\bmod 8$, $α$ even) and orthogonal ($L(s, ξ_{d,k})$ for $k \equiv α\bmod 8$, $α$ odd) subfamilies. For each such subfamily, we moreover compute explicit lower order terms in decreasing powers of $\log (K^2 \mathrm N(\mathfrak{f}_d))$.