English

Irreducibility properties of Carlitz' binomial coefficients for algebraic function fields

Number Theory 2023-10-04 v1 Commutative Algebra

Abstract

We study the class of univariate polynomials βk(X)\beta_k(X), introduced by Carlitz, with coefficients in the algebraic function field Fq(t)\mathbb F_q(t) over the finite field Fq\mathbb F_q with qq elements. It is implicit in the work of Carlitz that these polynomials form a Fq[t]\mathbb F_q[t]-module basis of the ring Int(Fq[t])={fFq(t)[X]f(Fq[t])Fq[t]}\text{Int}(\mathbb F_q[t]) = \{f \in \mathbb F_q(t)[X] \mid f(\mathbb F_q[t]) \subseteq \mathbb F_q[t]\} of integer-valued polynomials on the polynomial ring Fq[t]\mathbb F_q[t]. This stands in close analogy to the famous fact that a Z\mathbb Z-module basis of the ring Int(Z)\text{Int}(\mathbb Z) is given by the binomial polynomials (Xk)\binom{X}{k}. We prove, for k=qsk = q^s, where ss is a non-negative integer, that βk\beta_k is irreducible in Int(Fq[t])\text{Int}(\mathbb F_q[t]) and that it is even absolutely irreducible, that is, all of its powers βkm\beta_k^m with m>0m>0 factor uniquely as products of irreducible elements of this ring. As we show, this result is optimal in the sense that βk\beta_k is not even irreducible if kk is not a power of qq.

Keywords

Cite

@article{arxiv.2310.02061,
  title  = {Irreducibility properties of Carlitz' binomial coefficients for algebraic function fields},
  author = {Robert Tichy and Daniel Windisch},
  journal= {arXiv preprint arXiv:2310.02061},
  year   = {2023}
}
R2 v1 2026-06-28T12:39:26.754Z