The Willmore energy and curvature concentration

TL;DR

This paper establishes new lower bounds for the bending energy of isometric immersions of surfaces into three-dimensional space, linking curvature concentration and torsion measures to energy blowup rates, with applications in elasticity.

Contribution

It introduces novel lower bounds for the Willmore energy based on Gaussian curvature and Burgers vector, advancing understanding of curvature concentration effects.

Findings

Derived optimal blowup rates for curvature concentration scenarios.

Established lower bounds connecting energy to Gaussian curvature and torsion.

Applied results to elastic energy estimates in thin sheets.

Abstract

We study isometric immersions of a Riemannian surface $(\Omega,\frak{g})$, where $\Omega \subset \mathbb{R}^2$, into $\mathbb{R}^3$. We consider their bending energy, i.e., the square of the $L^2$-norm of their second fundamental form, which is equivalent to the Willmore functional. We obtain two new lower bounds for this energy, one in terms of the Gaussian curvature of the surface, and the other in terms of a Burgers vector -- a measure of non-flatness connected to torsion. These new estimates provide optimal blowup rates of the energy when the curvature is concentrated (e.g., in a conical geometry). In the more subtle case of dipoles of concentrated curvature, we use the Burgers vector estimates to obtain an optimal blowup rate in terms of the size of the system. Our motivation comes from non-Euclidean elasticity, in which cones and curvature-dipoles play a central role. The lower bounds derived in this work directly yield lower bounds for the elastic energy of thin elastic sheets. The derivation of the curvature-based lower bound involves an isoperimetric inequality for framed loops, which we believe to be of independent interest.