Barta Theorem for the p-Laplacian and Geometric Applications

Abstract

In this article, we develop a Barta-type formulation for the p-Laplacian on Riemannian manifolds, extending the approach of Cheung-Leung and Bessa-Montenegro from the linear to the nonlinear setting. This framework yields sharp lower bounds for the p-fundamental tone without any assumptions on boundary regularity. As applications, we obtain nonlinear extensions of Cheng's eigenvalue comparison theorem and the Cheng-Li-Yau estimate for p ≥ 2 in the context of minimal immersions. In particular, under the above assumptions, the domain is p-stable for the Schr\"odinger-type operator associated with the potential V = \|A\|p, where A denotes the second fundamental form of the minimal immersion. In addition, we establish a lower bound for the p-fundamental tone in the setting where the immersion has locally bounded mean curvature. Finally, we provide a Kazdan-Kramer type characterization of the p-fundamental tone, offering a unified and geometric perspective on spectral bounds for the operator p-Laplacian.

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