On the number of distinct prime factors of a sum of super-powers

Abstract

Given k, ∈ N+, let xi,j be, for 1 i k and 0 j , some fixed integers, and define, for every n ∈ N+, sn := Σi=1k Πj=0 xi,jnj. We prove that the following are equivalent: (a) There are a real θ > 1 and infinitely many indices n for which the number of distinct prime factors of sn is greater than the super-logarithm of n to base θ. (b) There do not exist non-zero integers a0,b0,…,a,b such that s2n=Πi=0 ai(2n)i and s2n-1=Πi=0 bi(2n-1)i for all n. We will give two different proofs of this result, one based on a theorem of Evertse (yielding, for a fixed finite set of primes S, an effective bound on the number of non-degenerate solutions of an S-unit equation in k variables over the rationals) and the other using only elementary methods. As a corollary, we find that, for fixed c1, x1, …,ck, xk ∈ N+, the number of distinct prime factors of c1 x1n+·s+ck xkn is bounded, as n ranges over N+, if and only if x1=·s=xk.