Extensions of unipotent groups, Massey products and Galois cohomology

TL;DR

This paper investigates the conditions under which four-fold Massey products vanish in mod p Galois cohomology, linking algebraic structures, local-global principles, and constructing a new finite group to facilitate the analysis.

Contribution

It introduces a new finite group U_5(\u211d_p) related to unipotent matrices, providing a natural and more manageable framework to study Massey products and their vanishing.

Findings

A sufficient condition for Massey product vanishing expressed via cup-products.

For local fields with roots of unity, the condition is also necessary.

A splitting variety is constructed to connect rational points with Massey product conditions.

Abstract

We study the vanishing of four-fold Massey products in mod p Galois cohomology. First, we describe a sufficient condition, which is simply expressed by the vanishing of some cup-products, in direct analogy with the work of Guillot, Min\'a\v{c} and Topaz for p=2. For local fields with enough roots of unity, we prove that this sufficient condition is also necessary, and we ask whether this is a general fact. We provide a simple splitting variety, that is, a variety which has a rational point if and only if our sufficient condition is satisfied. It has rational points over local fields, and so, if it satisfies a local-global principle, then the Massey Vanishing conjecture holds for number fields with enough roots of unity. At the heart of the paper is the construction of a finite group $\tilde U_5(\mathbb{F}_p)$, which has $U_5(\mathbb{F}_p)$ as a quotient. Here $U_n(\mathbb{F}_p)$ is the group of unipotent $n\times n$-matrices with entries in the field $\mathbb{F}_p$ with p elements; it is classical that $U_{n+1}(\mathbb{F}_p)$ is intimately related to n-fold Massey products. Although $\tilde U_5(\mathbb{F}_p)$ is much larger than $U_5(\mathbb{F}_p)$, its definition is very natural, and for our purposes, it is easier to study.