所有偶发apacry - like序列的新表示及其在同余上的应用

IF 0.7 4区数学 Q2 MATHEMATICS

Experimental Mathematics Pub Date : 2021-02-23 DOI:10.1080/10586458.2021.1982080

O. Gorodetsky

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引用次数: 8

摘要

Zagier、Almkvist和Zudilin以及Cooper在寻找某些二阶和三阶微分方程族的积分解时发现了零星的类Ap序列。对于所有15个偶发序列，我们发现了用洛朗多项式的常幂项表示的新表示。新的表示反过来导致序列的二项式表达式，与以前的表达式不同，它不涉及8的幂和3的幂。我们用这些来建立所有素数$p\ge3$和整数$n，k\ge1$的超余数$B_｛np^k｝\equiv B_｛np^｛k-1｝｝\bmod p^｛2k｝$，其中$B_n$是Zagier发现的序列，称为序列$\mathbf｛B｝$。此外，对于15个序列中的14个，在我们的表示中使用的洛朗多项式的牛顿多面体包含原点作为其唯一的内部积分点。这个性质使我们能够证明这14个零星序列满足Lucas同余的强形式，扩展了Malik和Straub的工作。此外，我们通过Delaygue最近的工作获得了这14个序列的$p$adic估值的下界。

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New Representations for all Sporadic Apéry-Like Sequences, With Applications to Congruences

Sporadic Ap\'ery-like sequences were discovered by Zagier, by Almkvist and Zudilin and by Cooper in their searches for integral solutions for certain families of second- and third-order differential equations. We find new representations, in terms of constant terms of powers of Laurent polynomials, for all the 15 sporadic sequences. The new representations in turn lead to binomial expressions for the sequences, which, as opposed to previous expressions, do not involve powers of 8 and powers of 3. We use these to establish the supercongruence $B_{np^k} \equiv B_{np^{k-1}} \bmod p^{2k}$ for all primes $p \ge 3$ and integers $n,k \ge 1$, where $B_n$ is a sequence discovered by Zagier and known as Sequence $\mathbf{B}$. Additionally, for 14 out of the 15 sequences, the Newton polytopes of the Laurent polynomials used in our representations contain the origin as their only interior integral point. This property allows us to prove that these 14 sporadic sequences satisfy a strong form of the Lucas congruences, extending work of Malik and Straub. Moreover, we obtain lower bounds on the $p$-adic valuation of these 14 sequences via recent work of Delaygue.

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来源期刊

Experimental Mathematics 数学-数学

CiteScore

1.70

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Experimental Mathematics publishes original papers featuring formal results inspired by experimentation, conjectures suggested by experiments, and data supporting significant hypotheses. Experiment has always been, and increasingly is, an important method of mathematical discovery. (Gauss declared that his way of arriving at mathematical truths was "through systematic experimentation.") Yet this tends to be concealed by the tradition of presenting only elegant, fully developed, and rigorous results. Experimental Mathematics was founded in the belief that theory and experiment feed on each other, and that the mathematical community stands to benefit from a more complete exposure to the experimental process. The early sharing of insights increases the possibility that they will lead to theorems: An interesting conjecture is often formulated by a researcher who lacks the techniques to formalize a proof, while those who have the techniques at their fingertips have been looking elsewhere. Even when the person who had the initial insight goes on to find a proof, a discussion of the heuristic process can be of help, or at least of interest, to other researchers. There is value not only in the discovery itself, but also in the road that leads to it.