TY - JOUR
T1 - Green function, Painlevé VI equation, and Eisenstein series of weight one
AU - Chen, Zhijie
AU - Kuo, Ting Jung
AU - Lin, Chang Shou
AU - Wang, Chin Lung
N1 - Publisher Copyright:
© 2018 Project Euclid.
PY - 2018/2
Y1 - 2018/2
N2 - The behavior and the location of singular points of a solution to Painlevé VI equation could encode important geometric properties. For example, Hitchin's formula indicates that singular points of algebraic solutions are exactly the zeros of Eisenstein series of weight one. In this paper, we study the problem: How many singular points of a solution λ(t) to the Painlevé VI equation with parameter ( 1/8 , -1/8 , 1/8 , 3/8 ) might have in C\{0, 1}? Here t0 ∈ C\{0, 1} is called a singular point of λ(t) if λ(t0) ∈ {0, 1, t0,∞}. Based on Hitchin's formula, we explore the connection of this problem with Green function and the Eisenstein series of weight one. Among other things, we prove: (i) There are only three solutions which have no singular points in C\{0, 1}. (ii) For a special type of solutions (called real solutions here), any branch of a solution has at most two singular points (in particular, at most one pole) in C \ {0, 1}. (iii) Any Riccati solution has singular points in C\{0, 1}. (iv) For each N ≥ 5 and N = 6, we calculate the number of the real j-values of zeros of the Eisenstein series EN1 (τ ; k1, k2) of weight one, where (k1, k2) runs over [0,N - 1]2 with gcd(k1, k2,N) = 1. The geometry of the critical points of the Green function on a flat torus Eτ, as τ varies in the moduli M1, plays a fundamental role in our analysis of the Painlevé VI equation. In particular, the conjectures raised in [23] on the shape of the domain Ω5 ⊂ M1, which consists of tori whose Green function has extra pair of critical points, are completely solved here.
AB - The behavior and the location of singular points of a solution to Painlevé VI equation could encode important geometric properties. For example, Hitchin's formula indicates that singular points of algebraic solutions are exactly the zeros of Eisenstein series of weight one. In this paper, we study the problem: How many singular points of a solution λ(t) to the Painlevé VI equation with parameter ( 1/8 , -1/8 , 1/8 , 3/8 ) might have in C\{0, 1}? Here t0 ∈ C\{0, 1} is called a singular point of λ(t) if λ(t0) ∈ {0, 1, t0,∞}. Based on Hitchin's formula, we explore the connection of this problem with Green function and the Eisenstein series of weight one. Among other things, we prove: (i) There are only three solutions which have no singular points in C\{0, 1}. (ii) For a special type of solutions (called real solutions here), any branch of a solution has at most two singular points (in particular, at most one pole) in C \ {0, 1}. (iii) Any Riccati solution has singular points in C\{0, 1}. (iv) For each N ≥ 5 and N = 6, we calculate the number of the real j-values of zeros of the Eisenstein series EN1 (τ ; k1, k2) of weight one, where (k1, k2) runs over [0,N - 1]2 with gcd(k1, k2,N) = 1. The geometry of the critical points of the Green function on a flat torus Eτ, as τ varies in the moduli M1, plays a fundamental role in our analysis of the Painlevé VI equation. In particular, the conjectures raised in [23] on the shape of the domain Ω5 ⊂ M1, which consists of tori whose Green function has extra pair of critical points, are completely solved here.
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U2 - 10.4310/jdg/1518490817
DO - 10.4310/jdg/1518490817
M3 - Article
AN - SCOPUS:85042052487
SN - 0022-040X
VL - 108
SP - 185
EP - 241
JO - Journal of Differential Geometry
JF - Journal of Differential Geometry
IS - 2
ER -