Erdos--Tur\'an Theorem and Eulerian Integers

Abstract

Our work is motivated by the fact that the norms of the Eulerian integers are related to the sums of form a2-ab+b2, providing a natural generalization for problems concerning products over sums or differences of integers. Let E be the set of Eulerian integers. We define ω N(x) as the number of distinct prime divisors of x∈ N, and ωE(x) as the number of distinct Euler prime divisors of x∈ E. By the Erdos--Tur\'an theorem, if A⊂ Z+ and |A|=3·2k-1 (k∈Z+), then ωN(Πa,b∈A,a≠b(a+b))≥k+1. We prove that if A ⊂ E is a finite set and ∈ E, then the value of ωE(Πa,b ∈ A, a ≠ b(a+ b)) has a lower bound of order |A|. Consequently, we provide lower bounds for A ⊂ N for both ωN(Πa,b ∈ A, a ≠ b(a2+ab+b2)) and ωN(Πa,b ∈ A, a ≠ b(a2-ab+b2)). We also give an upper bound for the minimum of ωN(Πa,b ∈ A, a ≠ b(a2+ab+b2)) with a computer program, if |A| 8 and sets whose largest element is relatively small. Furthermore, using a Diophantine number theoretical lemma of Gyory, S\'ark\"ozy, and Stewart, we give a lower bound of order |A| for ωN(Πa ∈ A, b ∈ B(f(a,b))) for a specific class of polynomials f ∈ Z[x,y] and finite sets A, B ⊂ Z.