# Endomorphism rings of supersingular elliptic curves over $\mathbb{F}_p$

**Authors:** Songsong Li, Yi Ouyang, Zheng Xu

arXiv: 1907.12185 · 2019-07-30

## TL;DR

This paper investigates the endomorphism rings of supersingular elliptic curves over finite fields, characterizes their structure based on prime conditions, and provides bounds and computational data related to their minimal primes and isogeny graphs.

## Contribution

It determines the local structure of supersingular elliptic curves' isogeny graphs and bounds the minimal primes associated with their endomorphism rings under GRH.

## Key findings

- At most two vertices over  in the isogeny graph are adjacent to a given supersingular elliptic curve.
- Under GRH, bounds are established for the minimal primes q_j associated with each curve.
- Numerical computations for p<2000 show M(p) generally exceeds  and is less than p log^2 p.

## Abstract

Let $p>3$ be a fixed prime. For a supersingular elliptic curve $E$ over $\mathbb{F}_p$ with $j$-invariant $j(E)\in \mathbb{F}_p\backslash\{0, 1728\}$, it is well known that the Frobenius map $\pi=((x,y)\mapsto (x^p, y^p))\in \mathrm{End}(E)$ satisfies ${\pi}^2=-p$. A result of Ibukiyama tells us that $\mathrm{End}(E)$ is a maximal order in $\mathrm{End}(E)\otimes \mathbb{Q}$ associated to a (minimal) prime $q$ satisfying $q\equiv 3 \bmod 8$ and the quadratic residue $\bigl(\frac{p}{q}\bigr)=-1$ according to $\frac{1+\pi}{2}\notin \mathrm{End}(E)$ or $\frac{1+\pi}{2}\in \mathrm{End}(E)$. Let $q_j$ denote the minimal $q$ for $E$ with $j=j(E)$. Firstly, we determine the neighborhood of the vertex $[E]$ in the supersingular $\ell$-isogeny graph if $\frac{1+\pi}{2}\notin \mathrm{End}(E)$ and $p>q\ell^2$ or $\frac{1+\pi}{2}\in \mathrm{End}(E)$ and $p>4q\ell^2$. In particular, under our assumption, we show that there are at most two vertices defined over $\mathbb{F}_p$ adjacent to $[E]$. Next, under GRH, we obtain the bound $M(p)$ of $q_j$ for all $j$ and estimate the number of supersingular elliptic curves with $q_j<c\sqrt{p}$. We also computer the upper bound $M(p)$ for all $p<2000$ numerically and show that $M(p)>\sqrt{p}$ except $p=11,23$ and $M(p)<p\log^2 p$ for all $p$.

## Full text

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## Figures

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## References

19 references — full list in the complete paper: https://tomesphere.com/paper/1907.12185/full.md

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Source: https://tomesphere.com/paper/1907.12185