Counting the number of n-periodic integral points of a discrete dynamical system with applications from arithmetic statistics, IV

Abstract

In this follow-up paper, we inspect a surprising relationship between the set of n-periodic points of a polynomial map d, c defined by d, c(z) = zd + c for all c, z ∈ Z and the coefficient c, where d>2 is an integer and n≥ 2 is any fixed integer. As before, we again wish to study counting problems which are inspired by the exciting advances of Bhargava-Shankar-Tsimerman and their collaborators on n-torsion point-counting in arithmetic statistics, and also by Hutz's conjecture along with Panraksa's work on n-periodic rational point-counting in arithmetic dynamics. In doing so, we then first prove that for any prime p≥ 3 and for any fixed (period) n∈ Z≥ 2, the average number of distinct n-periodic integral points of any p, c modulo p is unbounded or zero as c tends to infinity. Inspired further by a conjecture of Hutz on any p-1, c for any prime p≥ 5 in arithmetic dynamics, we then also prove that for any fixed (period) n∈ Z≥ 2, the average number of distinct n-periodic integral points of any p-1, c modulo p is 1 or 2 or 0 as c ∞. Finally, we then apply density, polynomial-counting, number field-counting, and Sato-Tate equidistribution results from arithmetic statistics, and thereby obtaining a stream of counting and statistical results on irreducible polynomials, number fields, and Artin L-functions that arise naturally in our polynomial discrete dynamical settings.