Flows of geometric structures
Abstract
We develop an abstract theory of flows of geometric -structures, i.e., flows of tensor fields defining -reductions of the frame bundle, for a closed and connected subgroup , on any connected and oriented -manifold with sufficient topology to admit such structures. The first part of the article sets up a unifying theoretical framework for deformations of -structures, by way of the natural infinitesimal action of on tensors combined with various bundle decompositions induced by -structures. We compute evolution equations for the intrinsic torsion under general flows of -structures and, as applications, we obtain general Bianchi-type identities for -structures, and, for closed manifolds, a general first variation formula for the -Dirichlet energy functional on the space of -structures. We then specialise the theory to the negative gradient flow of over isometric -structures, i.e., their harmonic flow. The core result is an almost monotonocity formula along the flow for a scale-invariant localised energy, similar to the classical formulae by Chen-Struwe for the harmonic map heat flow. This yields an -regularity theorem and an energy gap result for harmonic structures, as well as long-time existence for the flow under small initial energy, relative to the -norm of initial torsion, in the spirit of Chen-Ding. Moreover, below a certain energy level, the absence of a torsion-free isometric -structure in the initial homotopy class imposes the formation of finite-time singularities. These seemingly contrasting statements are illustrated by examples on flat -tori, so long as contains more than one element and the universal cover of is a sphere; e.g. when and , or and .
Cite
@article{arxiv.2211.05197,
title = {Flows of geometric structures},
author = {Daniel Fadel and Eric Loubeau and Andrés J. Moreno and Henrique N. Sá Earp},
journal= {arXiv preprint arXiv:2211.05197},
year = {2024}
}
Comments
v4: 61 pages, no figures. Final version, to appear in Journal f\"ur die reine und angewandte Mathematik. Completely revised article. Main corrections and clarifications: Lemma 2.4, proofs of Theorems 2.5, 2.7 and 2.10; Example 2.17 and Remark 2.18; proof of Lemma 2.23; Proposition 2.24; and proof of Theorem 2.29