Elliptic Curve Variants of the Least Quadratic Nonresidue Problem and Linnik's Theorem

Abstract

Let E1 and E2 be Q-nonisogenous, semistable elliptic curves over Q, having respective conductors NE1 and NE2 and both without complex multiplication. For each prime p, denote by aEi(p) := p+1-\#Ei(Fp) the trace of Frobenius. Under the assumption of the Generalized Riemann Hypothesis (GRH) for the convolved symmetric power L-functions L(s, Symi E1j E2) where i,j∈\0,1,2\, we prove an explicit result that can be stated succinctly as follows: there exists a prime p NE1NE2 such that aE1(p)aE2(p)<0 and \[ p < ( (32+o(1))· NE1 NE2)2. \] This improves and makes explicit a result of Bucur and Kedlaya. Now, if I⊂[-1,1] is a subinterval with Sato-Tate measure μ and if the symmetric power L-functions L(s, Symk E1) are functorial and satisfy GRH for all k 8/μ, we employ similar techniques to prove an explicit result that can be stated succinctly as follows: there exists a prime p NE1 such that aE1(p)/(2p)∈ I and \[ p < ((21+o(1)) · μ-2 (NE1/μ))2. \]