Relationship between Laplacian and Hessian on compact Lie groups

Question

If $f: \mathbb{R}^n \rightarrow \mathbb{R}$ is smooth and compactly supported, one has $$\int |\Delta f(\mathbf{x})|^2\,d\mathbf{x} = \int \| Hf(\mathbf{x}) \|_F^2\,d\mathbf{x}\,,$$ where $\Delta$ denotes the Laplacian, $H$ denotes the Hessian (matrix of second derivatives), and $\| \cdot\|_F^2$ denotes the Frobenius norm squared (the sum of squares of matrix entries). What can be said about compact Lie groups?

Specifically, I have two questions about this phenomenon:

Nomenclature: In this case where all norms are $L^2$, does this equality have a generally accepted name? What about the case when other norms are introduced?

Lie groups: I would like to understand in what sense this generalizes to compact Lie groups. What can be said about smooth $f: G \rightarrow \mathbb{R}$ (or $\mathbb{C}$)?

Answer 1

This has nothing to do with Lie groups, I believe. Let $M$ be a Riemannian manifold. The Bochner formula on $1$-forms states that $$\nabla^* \nabla \omega = (d \delta + \delta d)\omega - \mathrm{Ric}\,\omega.$$ Hence we have for any compactly supported function $f$ (writing round brackets for the $L^2$ scalar product) $$\|Hf\|_{L^2}^2 = \|\nabla d f\|_{L^2}^2 = (\nabla^* \nabla d f, df) = ((d \delta + \delta d - \mathrm{Ric})d f, df ) = (d\delta d f, d f) - (\mathrm{Ric}\, df, df)$$ Using that on functions, $\Delta f = \delta d f$, this is equal to $$(d \Delta f, df) - (\mathrm{Ric}\, df, df) = \|\Delta f\|_{L^2}^2 - (\mathrm{Ric}\, df, df)$$ This is a standard formula of Riemannian geometry.