Prime ideal races with several competitors (2508.04087v1)

Abstract: We investigate races among prime ideals in number fields when there are two or more competing conjugacy classes. In their work [4], Fiorilli and Jouve studied two-way races in number fields and showed that-unlike the classical setting of primes in arithmetic progressions-these biases can approach the extreme values of 0 and 1. They also identified when these biases tend toward one-half (as the degree of the extension grows), which we call ''moderate biases'' because that behavior mirrors the classical case. In this paper, we extend their analysis to races with r competing conjugacy classes (rway races) and precisely study the cases where these biases are moderate (meaning they tend to 1/r! as the discriminant of the extension grows). Our first main result is an explicit formula for the bias in any r-way race (for all r $\ge$ 2), generalizing the two-way formula of Fiorilli and Jouve [4] and Lamzouri's r-way expression in the classical case of residue classes modulo q [12], under the same hypotheses. Using this formula, we give a criterion characterizing completely, in the abelian case, r-moderate races. Surprisingly, once r $\ge$ 3 this criterion is independent of r, making the two-way race exceptional. We also construct families of number fields exhibiting such moderacy, we prove density results for the values of logarithmic densities and exhibit different behaviors of those densities between the cases r = 3 and r $\ge$ 4. and showed that its magnitude governs the bias: 2 ) converges to the extreme values 1 or 0. $\bullet$ Moderate bias. Under additional hypotheses (automatically satisfied in the abelian case), if L/K (C 1 , C 2 ) $\rightarrow$ 1/2, mirroring the classical prime-ideal race studied by Rubinstein-Sarnak and Fiorilli-Martin. Applying this criterion to several explicit families such that the degree grows to $\infty$, Fiorilli and Jouve produced examples of both moderate and extreme biases along families of number fields. In the same spirit, Bailleul [1] investigated dihedral and quaternion extensions, uncovering further families in which the densities not only approach the value 1/2 but can again be made to lie arbitrarily near the extremes, while also highlighting the influence of central zeros of Artin L-functions on the behavior of those densities.