Murmurations for elliptic curves ordered by height
Abstract
He, Lee, Oliver, and Pozdnyakov~\cite{HLOP} have empirically observed that the average of the th coefficients of the -functions of elliptic curves of particular ranks in a given range of conductors appears to approximate a continuous function of , depending primarily on the parity of the rank. Hence the sum of th coefficients against the root number also appears to approximate a continuous function, dubbed the murmuration density. However, it is not clear from this numerical data how to obtain an explicit formula for the murmuration density. Convergence of similar averages was proved by Zubrilina~\cite{Zubrilina} for modular forms of weight (of which elliptic curves form a thin subset) and analogous results for other families of automorphic forms have been obtained in further work~\cite{BBLLD,LOP}. Each of these works gives an explicit formula for the murmuration density. We consider a variant problem where the elliptic curves are ordered by naive height, and the th coefficients are averaged over in a fixed interval. We give a conjecture for the murmuration density in this case, as an explicit but complicated sum of Bessel functions. This conjecture is motivated by a theorem about a variant problem where we sum the th coefficients for with no small prime factors against a smooth weight function. We test this conjecture for elliptic curves of naive height up to and find good agreement with the data. The theorem is proved using the Voronoi summation formula, and the method should apply to many different families of -functions. By a similar approach, we give a prediction murmuration density for elliptic curves of prime conductor, ordered by conductor, again matching the data but lacking a motivating theorem. This is the first work to give an explicit formula for the murmuration density of a family of elliptic curves, in any ordering.
Cite
@article{arxiv.2504.12295,
title = {Murmurations for elliptic curves ordered by height},
author = {Will Sawin and Andrew V. Sutherland},
journal= {arXiv preprint arXiv:2504.12295},
year = {2025}
}
Comments
Added Section 1.5; 48 pages, 5 figures