Full Galois groups of polynomials with slowly growing coefficients

IF 0.9 3区数学 Q2 MATHEMATICS Bulletin of the London Mathematical Society Pub Date : 2025-02-04 DOI:10.1112/blms.70008

Lior Bary-Soroker, Noam Goldgraber

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Abstract

Choose a polynomial $f$ uniformly at random from the set of all monic polynomials of degree $n$ with integer coefficients in the box ${[- L, L]}^{n}$ . The main result of the paper asserts that if $L = L (n)$ grows to infinity, then the Galois group of $f$ is the full symmetric group, asymptotically almost surely, as $n \to \infty$ . When $L$ grows rapidly to infinity, say $L > n^{7}$ , this theorem follows from a result of Gallagher. When $L$ is bounded, the analog of the theorem is open, while the state-of-the-art is that the Galois group is large in the sense that it contains the alternating group (if $L < 17$ , it is conditional on the Extended Riemann Hypothesis). Hence the most interesting case of the theorem is when $L$ grows slowly to infinity. Our method works for more general independent coefficients.

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系数缓慢增长的多项式的全伽罗瓦群

从方框[−L]中所有n次$n$的整数系数一元多项式集合中均匀随机地选择一个多项式f $f$，L] n $[-L,L]^n$。本文的主要结果表明，如果L = L (n) $L=L(n)$增长到无穷，则f $f$的伽罗瓦群是完全对称群，渐近几乎肯定；当n→∞$n\rightarrow \infty$。当L $L$快速增长到无穷大时，设L ＆gt；n7 $L>n^7$，这个定理是由Gallagher的结果推导出来的。当L $L$有界时，该定理的类比是开放的，而实际情况是伽罗瓦群是大的，因为它包含交替群(如果L ＆lt；17 $L< 17$，它以扩展黎曼假设为条件)。因此，这个定理最有趣的情况是当L $L$缓慢增长到无穷大时。我们的方法适用于更一般的独立系数。

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