A theory of generalized Lamé curves

Abstract

We study the generalized Lam'e equation (GLE) on an elliptic curve E with multiple regular singularities p = (pi)i = 1r of weights n = (ni)i = 1r. By analyzing the locus admitting quasi-periodic solutions, we construct two fundamental algebraic curves: (i) The generalized Lam'e curve (GLC), Yn, p, which lies in an affine bundle over Symn E for total weight n:=Σ ni ∈ Z≥ 0 and parametrizes generalized Hermite--Halphen ansatz solutions. (ii) The log-free curve, Vn, p, a non-complete intersection variety arising when all ni ∈ 12N, which we prove is a reduced curve, confirming a conjecture of Wang. We analyze the GLC as an algebraic family over the pole configuration space. By studying the addition mapσ Symn E E,where we establish a generically finite, universal degree formula, we show that the geometry of boundary degenerations under pole collisions perfectly mirrors the tensor algebra of sl2(C)-modules within the BGG category O. This provides the local structural limits needed to establish the global flatness of the GLC. Furthermore, we develop a framework of twisted isomonodromic deformations and construct (n, p)-deformed pre-modular forms parameterized by twisted monodromy data (t,s). Their vanishing solves the underlying monodromy problem and factorizes along boundary strata, allowing an arbitrary configuration to be continuously deformed down to the classical Lam'e equation. Finally, using an asymptotic scaling technique, we completely solve the Treibich conjecture for r=2 symmetric pairs, extend it to r ≤ 4, and propose a general formula enumerating symmetric finite-gap KdV potentials for all r.