English

Iterating additive polynomials over finite fields

Number Theory 2025-08-13 v1

Abstract

Let qq be a power of a prime pp, let Fq\mathbb F_q be the finite field with qq elements and, for each nonconstant polynomial FFq[X]F\in \mathbb F_{q}[X] and each integer n1n\ge 1, let sF(n)s_F(n) be the degree of the splitting field (over Fq\mathbb F_q) of the iterated polynomial F(n)(X)F^{(n)}(X). In 1999, Odoni proved that sA(n)s_A(n) grows linearly with respect to nn if AFq[X]A\in \mathbb F_q[X] is an additive polynomial not of the form aXphaX^{p^h}; moreover, if q=pq=p and B(X)=XpXB(X)=X^p-X, he obtained the formula sB(n)=plogpns_{B}(n)=p^{\lceil \log_p n\rceil}. In this paper we note that sF(n)s_F(n) grows at least linearly unless FFq[X]F\in \mathbb F_q[X] has an exceptional form and we obtain a stronger form of Odoni's result, extending it to affine polynomials. In particular, we prove that if AA is additive, then sA(n)s_A(n) resembles the step function plogpnp^{\lceil \log_p n\rceil} and we indeed have the identity sA(n)=αplogpβns_A(n)=\alpha p^{\lceil \log_p \beta n\rceil} for some α,βQ\alpha, \beta\in \mathbb Q, unless AA presents a special irregularity of dynamical flavour. As applications of our main result, we obtain statistics for periodic points of linear maps over Fqi\mathbb F_{q^i} as i+i\to +\infty and for the factorization of iterates of affine polynomials over finite fields.

Keywords

Cite

@article{arxiv.2502.19141,
  title  = {Iterating additive polynomials over finite fields},
  author = {Lucas Reis},
  journal= {arXiv preprint arXiv:2502.19141},
  year   = {2025}
}
R2 v1 2026-06-28T21:58:42.392Z