Co-Axial Metrics on the Sphere and Algebraic Numbers

Abstract

In this paper, we consider the following curvature equation u+ eu=4π((θ0-1)δ0+(θ1-1)δ1 +Σj=1n+m(θj'-1)δtj) in\ R2, u(x)=-2(1+θ∞)|x|+O(1) as \ |x|∞, where θ0, θ1, θ∞, and θj' are positive non-integers for 1 j n, while θj'∈N≥ 2 are integers for n+1 j n+m. Geometrically, a solution u gives rise to a conical metric ds2=12 eu| dx|2 of curvature 1 on the sphere, with conical singularities at 0, 1, ∞, and tj, 1 j n+m, with angles 2πθ0, 2πθ1, 2πθ∞, and 2πθj' at 0, 1, ∞, and tj, respectively. The metric ds2 or the solution u is called co-axial, which was introduced by Mondello and Panov, if there is a developing map h(x) of u such that the projective monodromy group is contained in the unit circle. The sufficient and necessary conditions in terms of angles for the existence of such metrics were obtained by Mondello-Panov (2016) and Eremenko (2020). In this paper, we fix the angles and study the locations of the singularities t1,…,tn+m. Let A⊂Cn+m be the set of those (t1,…,tn+m)'s such that a co-axial metric exists, among other things we prove that (i) If m=1, i.e., there is only one integer θn+1' among θj', then A is a finite set. Moreover, for the case n=0, we obtain a sharp bound of the cardinality of the set A. We apply a result due to Eremenko, Gabrielov, and Tarasov (2016) and the monodromy of hypergeometric equations to obtain such a bound. (ii) If m 2, then A is an algebraic set of dimension ≤ m-1.

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