Abstract
This article concerns the study of a new invariant bilinear form $\mathcal B$ on the space of automorphic forms of a split reductive group $G$ over a function field. We define $\mathcal B$ using the asymptotics maps from Bezrukavnikov-Kazhdan and Sakellaridis-Venkatesh, which involve the geometry of the wonderful compactification of $G$. We show that $\mathcal B$ is naturally related to miraculous duality in the geometric Langlands program through the functions-sheaves dictionary. In the proof, we highlight the connection between the classical non-Archimedean Gindikin-Karpelevich formula and certain factorization algebras acting on geometric Eisenstein series. We then give another definition of $\mathcal B$ using the constant term operator and the inverse of the standard intertwining operator. The form $\mathcal B$ defines an invertible operator $L$ from the space of compactly supported automorphic forms to a new space of "pseudo-compactly" supported automorphic forms. We give a formula for $L^{-1}$ in terms of pseudo-Eisenstein series and constant term operators which suggests that $L^{-1}$ is an analog of the Aubert-Zelevinsky involution.
Highlights
1.1.1 MotivationLet G be a connected reductive group over a perfect field k
If P − is a parabolic subgroup opposite to P, G/U is closely related to the more symmetrically defined variety XP = (G/U × G/U −)/(P ∩ P −), which is quasi-affine. This variety XP is called a boundary degeneration of G in [60], and it is a central object in the geometric proof of Bernstein’s Second Adjointness Theorem in the theory of p-adic groups given in [10]. We note that this proof and the space XP are closely related to the study of geometric constant term functors in [24]
We show in §1.3.2 that this monoid may be realized as a retract of G/U, the spectrum of regular functions on the quasi-affine variety G/U
Summary
Our interest in the operator R originates from the classical theory of automorphic forms. Let B denote the subgroup of upper triangular matrices. The global intertwining operator plays an important role in the theory of Eisenstein series and their constant terms [16, §3.7]. The results of this chapter are used to prove invertibility of the global intertwining operator in [27]. This in turn gives explicit formulas for the bilinear form B defined in Chapter 2 in the case G = SL(2) over any global field. The Radon transform has been studied extensively by analysts ([33], [39], [40]) over slightly different function spaces
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