符号$(13,13,n)$的模方法和费马方程的一些推广

Pub Date : 2018-02-12 DOI:10.5565/publmat6722309

Nicolas Billerey, I. Chen, Lassina Dembélé, L. Dieulefait, Nuno Freitas

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引用次数: 9

摘要

我们提供了模块化方法的几个扩展，这些扩展是由完成先前工作的问题所激发的，以证明对于任何整数$n \geq 2$，方程\[ x^{13} + y^{13} = 3 z^n \]没有非平凡解。特别地，我们提出了四种消除技术，它们基于:(1)在全实域上建立某些残差伽罗瓦表示的可约性;(2)将惯性参数像推广到阿贝尔曲面的设置;(3)在不使用通常不切实际的Sturm界的情况下建立Hilbert模形式的同余;(4)结合经典下降法和模数法的单元筛参数。这些扩展具有更广泛的适用性，并进一步证明了在模方法的框架内获得一类广义费马方程的完全解是可能的。为了进一步说明这一点，我们完成了annie - siksek的一个定理，证明对于$\ell, m\ge 5$，方程$x^{2\ell} + y^{2m} = z^{13}$的唯一解是平凡解。

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Some extensions of the modular method and Fermat equations of signature $(13,13,n)$

We provide several extensions of the modular method which were motivated by the problem of completing previous work to prove that, for any integer $n \geq 2$, the equation \[ x^{13} + y^{13} = 3 z^n \] has no non-trivial solutions. In particular, we present four elimination techniques which are based on: (1) establishing reducibility of certain residual Galois representations over a totally real field; (2) generalizing image of inertia arguments to the setting of abelian surfaces; (3) establishing congruences of Hilbert modular forms without the use of often impractical Sturm bounds; and (4) a unit sieve argument which combines information from classical descent and the modular method. The extensions are of broader applicability and provide further evidence that it is possible to obtain a complete resolution of a family of generalized Fermat equations by remaining within the framework of the modular method. As a further illustration of this, we complete a theorem of Anni-Siksek to show that, for $\ell, m\ge 5$, the only solutions to the equation $x^{2\ell} + y^{2m} = z^{13}$ are the trivial ones.

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