Weitzenböck identity

Not to be confused with Weitzenböck's inequality.

In mathematics, in particular in differential geometry, mathematical physics, and representation theory a Weitzenböck identity, named after Roland Weitzenböck, expresses a relationship between two second-order elliptic operators on a manifold with the same leading symbol. (The origins of this terminology seem doubtful, however, as there does not seem to be any evidence that such identities ever appeared in Weitzenböck's work.) Usually Weitzenböck formulae are implemented for G-invariant self-adjoint operators between vector bundles associated to some principal G-bundle, although the precise conditions under which such a formula exists are difficult to formulate. Instead of attempting to be completely general, then, this article presents three examples of Weitzenböck identities: from Riemannian geometry, spin geometry, and complex analysis.

Riemannian geometry

In Riemannian geometry there are two notions of the Laplacian on differential forms over an oriented compact Riemannian manifold M. The first definition uses the divergence operator δ defined as the formal adjoint of the de Rham operator d:

\int_M \langle \alpha,\delta\beta\rangle := \int_M\langle d\alpha,\beta\rangle

where α is any p-form and β is any (p + 1)-form, and \langle -,-\rangle is the metric induced on the bundle of (p + 1)-forms. The usual form Laplacian is then given by

\Delta = d\delta +\delta d.

On the other hand, the Levi-Civita connection supplies a differential operator

\nabla:\Omega^pM\rightarrow T^*M\otimes\Omega^pM ,

where ΩpM is the bundle of p-forms and TM is the cotangent bundle of M. The Bochner Laplacian is given by

\Delta'=\nabla^*\nabla

where \nabla^* is the adjoint of \nabla.

The Weitzenböck formula then asserts that

\Delta' - \Delta = A

where A is a linear operator of order zero involving only the curvature.

The precise form of A is given, up to an overall sign depending on curvature conventions, by

A=\frac{1}{2}\langle R(\theta,\theta)\#,\#\rangle + \operatorname{Ric}(\theta,\#) ,

where

  • R is the Riemann curvature tensor,
  • Ric is the Ricci tensor,
  • \theta:T^*M\otimes\Omega^pM\rightarrow\Omega^{p+1}M is the map that takes the wedge product of a 1-form and p-form and gives a (p+1)-form,
  • \#:\Omega^{p+1}M\rightarrow T^*M\otimes\Omega^pM is the universal derivation inverse to θ on 1-forms.

Spin geometry

If M is an oriented spin manifold with Dirac operator ð, then one may form the spin Laplacian Δ = ð2 on the spin bundle. On the other hand, the Levi-Civita connection extends to the spin bundle to yield a differential operator

\nabla:SM\rightarrow T^*M\otimes SM.

As in the case of Riemannian manifolds, let \Delta'=\nabla^*\nabla. This is another self-adjoint operator and, moreover, has the same leading symbol as the spin Laplacian. The Weitzenböck formula yields:

\Delta'-\Delta=-\frac{1}{4}Sc

where Sc is the scalar curvature. This result is also known as the Lichnerowicz formula.

Complex differential geometry

If M is a compact Kähler manifold, there is a Weitzenböck formula relating the \bar{\partial}-Laplacian (see Dolbeault complex) and the Euclidean Laplacian on (p,q)-forms. Specifically, let

\Delta=\bar{\partial}^*\bar{\partial}+\bar{\partial}\bar{\partial}^*, and
\Delta'=-\sum_k\nabla_k\nabla_{\bar{k}} in a unitary frame at each point.

According to the Weitzenböck formula, if α ε Ω(p,q)M, then

Δ'α  Δα = A(α)

where A is an operator of order zero involving the curvature. Specifically,

if \alpha=\alpha_{i_1i_2\dots i_p\bar{j}_1\bar{j}_2\dots\bar{j}_q} in a unitary frame, then
A(\alpha)=-\sum_{k,j_s} \operatorname{Ric}_{\bar{j}_\alpha}^{\bar{k}}\alpha_{i_1i_2\dots i_p\bar{j}_1\bar{j}_2\dots\bar{k}\dots\bar{j}_q} with k in the s-th place.

Other Weitzenböck identities

See also

References

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