# Laplace operators in differential geometry

In differential geometry there are a number of second-order, linear, elliptic differential operators bearing the name **Laplacian**. This article provides an overview of some of them.

## Connection Laplacian

The **connection Laplacian**, also known as the **rough Laplacian**, is a differential operator acting on the various tensor bundles of a manifold, defined in terms of a Riemannian- or pseudo-Riemannian metric. When applied to functions (i.e. tensors of rank 0), the connection
Laplacian is often called the Laplace–Beltrami operator. It is defined as the trace of the second covariant derivative:

where *T* is any tensor, is the Levi-Civita connection associated to the metric, and the trace is taken with respect to
the metric. Recall that the second covariant derivative of *T* is defined as

Note that with this definition, the connection Laplacian has negative spectrum. On functions, it agrees with the operator given as the divergence of the gradient.

If connection of interest is Levi-Civita connection one can find a convenient formula for Laplacian of scalar function in terms of partial derivatives with respect to chosen coordinates:

where is scalar function, is absolute value of determinant of metric (the use of absolute value is necessary in Pseudo Riemmanian case, for example in General Relativity) and denotes inverse of the metric tensor

## Hodge Laplacian

The **Hodge Laplacian**, also known as the **Laplace–de Rham operator**, is a differential operator acting on differential forms. (Abstractly,
it is a second order operator on each exterior power of the cotangent bundle.) This operator is defined on any manifold equipped with
a Riemannian- or pseudo-Riemannian metric.

where d is the exterior derivative or differential and δ is the codifferential. The Hodge Laplacian on a compact manifold has nonnegative spectrum.

The connection Laplacian may also be taken to act on differential forms by restricting it to act on skew-symmetric tensors. The connection Laplacian differs from the Hodge Laplacian by means of a Weitzenböck identity.

## Bochner Laplacian

The **Bochner Laplacian** is defined differently from the connection Laplacian, but the two will turn out to differ only by a sign, whenever the former is defined. Let *M* be a compact, oriented manifold equipped with a metric. Let *E* be a vector bundle over *M* equipped a fiber metric and a compatible connection, . This connection gives rise to a differential operator

where denotes smooth sections of *E*, and *T*^{*}M is the cotangent bundle of *M*. It is possible to take the -adjoint of , giving a differential operator

The **Bochner Laplacian** is given by

which is a second order operator acting on sections of the vector bundle *E*. Note that the connection Laplacian and Bochner Laplacian differ only by a sign:

## Lichnerowicz Laplacian

The **Lichnerowicz Laplacian**^{[1]} is defined on symmetric tensors by taking to be the symmetrized covariant derivative. The Lichnerowicz Laplacian is then defined by , where is the formal adjoint. The Lichnerowicz Laplacian differs from the usual tensor Laplacian by a Weitzenbock formula involving the Riemann curvature tensor, and has natural applications in the study of Ricci flow and the prescribed Ricci curvature problem.

## Conformal Laplacian

On a Riemannian manifold, one can define the **conformal Laplacian** as an operator on smooth functions; it differs from the Laplace–Beltrami operator by a term involving the scalar curvature of the underlying metric. In dimension *n* ≥ 3, the conformal Laplacian, denoted *L*, acts on a smooth function *u* by

where Δ is the Laplace-Beltrami operator (of negative spectrum), and *R* is the scalar curvature. This operator often makes an appearance when studying how the scalar curvature behaves under a conformal change of a Riemannian metric. If *n* ≥ 3 and *g* is a metric and *u* is a smooth, positive function, then the conformal metric

has scalar curvature given by

## See also

## References

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