Sign Changes of the Liouville function on quadratics

Abstract

Let λ (n) denote the Liouville function. Complementary to the prime number theorem, Chowla conjectured that 1mm Conjecture (Chowla). equation a.1 Σn x λ (f(n)) =o(x) equation for any polynomial f(x) with integer coefficients which is not of form bg(x)2. 1mm The prime number theorem is equivalent to a.1 when f(x)=x. Chowla's conjecture is proved for linear functions but for the degree greater than 1, the conjecture seems to be extremely hard and still remains wide open. One can consider a weaker form of Chowla's conjecture, namely, 1mm Conjecture 1 (Cassaigne, et al). If f(x) ∈ [x] and is not in the form of bg2(x) for some g(x)∈ [x], then λ (f(n)) changes sign infinitely often. Clearly, Chowla's conjecture implies Conjecture 1. Although it is weaker, Conjecture 1 is still wide open for polynomials of degree >1. In this article, we study Conjecture 1 for the quadratic polynomials. One of our main theorems is Theorem 1. Let f(x) = ax2+bx +c with a>0 and l be a positive integer such that al is not a perfect square. Then if the equation f(n)=lm2 has one solution (n0,m0) ∈ 2, then it has infinitely many positive solutions (n,m) ∈ 2. As a direct consequence of Theorem 1, we prove some partial results of Conjecture 1 for quadratic polynomials are also proved by using Theorem 1.