Fourier transforms of irregular holonomic D-modules, singularities at infinity of meromorphic functions and irregular characteristic cycles

TL;DR

This paper advances the understanding of Fourier transforms of irregular holonomic D-modules by connecting their singularities and irregularities to geometric features using new methods like meromorphic vanishing cycles.

Contribution

It introduces a geometric description of irregularities and exponential factors of Fourier transforms in higher dimensions, incorporating irregular characteristic cycles and rank jumps.

Findings

Fourier transforms' irregularities are described geometrically via stationary phase.

New methods for studying singularities of meromorphic functions are developed.

Higher-dimensional Fourier transforms exhibit rank jumps due to singularities.

Abstract

Based on the recent developments in the irregular Riemann-Hilbert correspondence for holonomic D-modules and the Fourier-Sato transforms for enhanced ind-sheaves, we study the Fourier transforms of some irregular holonomic D-modules. For this purpose, the singularities of rational and meromorphic functions on complex affine varieties will be studied precisely, with the help of some new methods and tools such as meromorphic vanishing cycle functors. As a consequence, we show that the exponential factors and the irregularities of the Fourier transform of a holonomic D-module are described geometrically by the stationary phase method, as in the classical case of dimension one. A new feature in the higher-dimensional case is that we have some extra rank jump of the Fourier transform produced by the singularities of the linear perturbations of the exponential factors at their points of indeterminacy. In the course of our study, not necessarily homogeneous Lagrangian cycles that we call irregular characteristic cycles will play a crucial role.