Linnik's Theorem for Sato-Tate Laws on Elliptic Curves with Complex Multiplication

Abstract

Let E/Q be an elliptic curve with complex multiplication (CM), and for each prime p of good reduction, let aE(p) = p + 1 - \#E(Fp) denote the trace of Frobenius. By the Hasse bound, aE(p) = 2p θp for a unique θp ∈ [0, π]. In this paper, we prove that the least prime p such that θp ∈ [α, β] ⊂ [0, π] satisfies \[ p (NEβ - α)A, \] where NE is the conductor of E and the implied constant and exponent A > 2 are absolute and effectively computable. Our result is an analogue for CM elliptic curves of Linnik's Theorem for arithmetic progressions, which states that the least prime p a q for (a,q)=1 satisfies p qL for an absolute constant L > 0.