# Non-spherical Harish-Chandra Fourier transforms on real reductive groups

**Authors:** Olufemi O. Oyadare

arXiv: 1907.00717 · 2022-02-03

## TL;DR

This paper extends the Harish-Chandra Fourier transform theory to the full Schwartz convolution algebra on real reductive groups, establishing a topological algebra isomorphism without restrictions on the group, p, or functions.

## Contribution

It constructs an image of the Harish-Chandra Fourier transform for the entire Schwartz convolution algebra, removing previous restrictions and enabling comprehensive harmonic analysis on real reductive groups.

## Key findings

- Proves the Fourier transform is a topological algebra isomorphism on the full Schwartz algebra
- Provides a decomposition of the transform's image for full harmonic analysis
- Extends the transform to all p-tempered distributions and zero-Schwartz spaces

## Abstract

The Harish-Chandra Fourier transform, $f\mapsto\mathcal{H}f,$ is a linear topological algebra isomorphism of the spherical (Schwartz) convolution algebra $\mathcal{C}^{p}(G//K)$ (where $K$ is a maximal compact subgroup of any arbitrarily chosen group $G$ in the Harish-Chandra class and $0<p\leq2$) onto the (Schwartz) multiplication algebra $\bar{\mathcal{Z}}({\mathfrak{F}}^{\epsilon})$ (of $\mathfrak{w}-$invariant members of $\mathcal{Z}({\mathfrak{F}}^{\epsilon}),$ with $\epsilon=(2/p)-1$). This is the well-known Trombi-Varadarajan theorem for spherical functions on the real reductive group, $G.$ Even though $\mathcal{C}^{p}(G//K)$ is a closed subalgebra of $\mathcal{C}^{p}(G),$ a similar theorem cannot however be proved for the full Schwartz convolution algebra $\mathcal{C}^{p}(G)$ except; for $\mathcal{C}^{p}(G/K)$ (whose method is essentially that of Trombi-Varadarajan, as shown by M. Eguchi); for few specific examples of groups (notably $G=SL(2,\R)$) and; for some notable values of $p$ (with restrictions on $G$ and/or on members of $\;\mathcal{C}^{p}(G)$). In this paper, we construct an appropriate image of the Harish-Chandra Fourier transform for the full Schwartz convolution algebra $\mathcal{C}^{p}(G),$ without any restriction on any of $G,p$ and members of $\;\mathcal{C}^{p}(G).$ Our proof, that the Harish-Chandra Fourier transform, $f\mapsto\mathcal{H}f,$ is a linear topological algebra isomorphism on $\mathcal{C}^{p}(G),$ equally shows that its image $\mathcal{C}^{p}(\widehat{G})$ can be nicely decomposed, that the full invariant harmonic analysis is available and implies that the definition of the Harish-Chandra Fourier transform may now be extended to include all $p-$tempered distributions on $G$ and to the zero-Schwartz spaces

## Full text

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Source: https://tomesphere.com/paper/1907.00717