Cotton tensor

Last updated December 29, 2023

In differential geometry, the Cotton tensor on a (pseudo)-Riemannian manifold of dimension n is a third-order tensor concomitant of the metric. The vanishing of the Cotton tensor for n = 3 is necessary and sufficient condition for the manifold to be locally conformally flat. By contrast, in dimensions n ≥ 4, the vanishing of the Cotton tensor is necessary but not sufficient for the metric to be conformally flat; instead, the corresponding necessary and sufficient condition in these higher dimensions is the vanishing of the Weyl tensor, while the Cotton tensor just becomes a constant times the divergence of the Weyl tensor. For n < 3 the Cotton tensor is identically zero. The concept is named after Émile Cotton.

The proof of the classical result that for n = 3 the vanishing of the Cotton tensor is equivalent to the metric being conformally flat is given by Eisenhart using a standard integrability argument. This tensor density is uniquely characterized by its conformal properties coupled with the demand that it be differentiable for arbitrary metrics, as shown by ( Aldersley 1979 ).

Recently, the study of three-dimensional spaces is becoming of great interest, because the Cotton tensor restricts the relation between the Ricci tensor and the energy–momentum tensor of matter in the Einstein equations and plays an important role in the Hamiltonian formalism of general relativity.

Definition

In coordinates, and denoting the Ricci tensor by R_ij and the scalar curvature by R, the components of the Cotton tensor are

C_{ijk}=\nabla _{k}R_{ij}-\nabla _{j}R_{ik}+{\frac {1}{2(n-1)}}\left(\nabla _{j}Rg_{ik}-\nabla _{k}Rg_{ij}\right).

The Cotton tensor can be regarded as a vector valued 2-form, and for n = 3 one can use the Hodge star operator to convert this into a second order trace free tensor density

C_{i}^{j}=\nabla _{k}\left(R_{li}-{\frac {1}{4}}Rg_{li}\right)\epsilon ^{klj},

sometimes called the Cotton–York tensor.

Properties

Conformal rescaling

Under conformal rescaling of the metric ${\tilde {g}}=e^{2\omega }g$ for some scalar function $\omega$ . We see that the Christoffel symbols transform as

{\widetilde {\Gamma }}_{\beta \gamma }^{\alpha }=\Gamma _{\beta \gamma }^{\alpha }+S_{\beta \gamma }^{\alpha }

where $S_{\beta \gamma }^{\alpha }$ is the tensor

S_{\beta \gamma }^{\alpha }=\delta _{\gamma }^{\alpha }\partial _{\beta }\omega +\delta _{\beta }^{\alpha }\partial _{\gamma }\omega -g_{\beta \gamma }\partial ^{\alpha }\omega

The Riemann curvature tensor transforms as

{{\widetilde {R}}^{\lambda }}{}_{\mu \alpha \beta }={R^{\lambda }}_{\mu \alpha \beta }+\nabla _{\alpha }S_{\beta \mu }^{\lambda }-\nabla _{\beta }S_{\alpha \mu }^{\lambda }+S_{\alpha \rho }^{\lambda }S_{\beta \mu }^{\rho }-S_{\beta \rho }^{\lambda }S_{\alpha \mu }^{\rho }

In $n$ -dimensional manifolds, we obtain the Ricci tensor by contracting the transformed Riemann tensor to see it transform as

{\widetilde {R}}_{\beta \mu }=R_{\beta \mu }-g_{\beta \mu }\nabla ^{\alpha }\partial _{\alpha }\omega -(n-2)\nabla _{\mu }\partial _{\beta }\omega +(n-2)(\partial _{\mu }\omega \partial _{\beta }\omega -g_{\beta \mu }\partial ^{\lambda }\omega \partial _{\lambda }\omega )

Similarly the Ricci scalar transforms as

{\widetilde {R}}=e^{-2\omega }R-2e^{-2\omega }(n-1)\nabla ^{\alpha }\partial _{\alpha }\omega -(n-2)(n-1)e^{-2\omega }\partial ^{\lambda }\omega \partial _{\lambda }\omega

Combining all these facts together permits us to conclude the Cotton-York tensor transforms as

{\widetilde {C}}_{\alpha \beta \gamma }=C_{\alpha \beta \gamma }+(n-2)\partial _{\lambda }\omega {W_{\beta \gamma \alpha }}^{\lambda }

or using coordinate independent language as

{\tilde {C}}=C\;+(n-2)\;\operatorname {grad} \,\omega \;\lrcorner \;W,

where the gradient is contracted with the Weyl tensor W.

Symmetries

The Cotton tensor has the following symmetries:

C_{ijk}=-C_{ikj}\,

and therefore

C_{[ijk]}=0.\,

In addition the Bianchi formula for the Weyl tensor can be rewritten as

\delta W=(3-n)C,\,

where $\delta$ is the positive divergence in the first component of W.

Related Research Articles

In physics, Kaluza–Klein theory is a classical unified field theory of gravitation and electromagnetism built around the idea of a fifth dimension beyond the common 4D of space and time and considered an important precursor to string theory. In their setup, the vacuum has the usual 3 dimensions of space and one dimension of time but with another microscopic extra spatial dimension in the shape of a tiny circle. Gunnar Nordström had an earlier, similar idea. But in that case, a fifth component was added to the electromagnetic vector potential, representing the Newtonian gravitational potential, and writing the Maxwell equations in five dimensions.

In particle physics, the Dirac equation is a relativistic wave equation derived by British physicist Paul Dirac in 1928. In its free form, or including electromagnetic interactions, it describes all spin-1⁄2 massive particles, called "Dirac particles", such as electrons and quarks for which parity is a symmetry. It is consistent with both the principles of quantum mechanics and the theory of special relativity, and was the first theory to account fully for special relativity in the context of quantum mechanics. It was validated by accounting for the fine structure of the hydrogen spectrum in a completely rigorous way.

In the mathematical field of differential geometry, the Riemann curvature tensor or Riemann–Christoffel tensor is the most common way used to express the curvature of Riemannian manifolds. It assigns a tensor to each point of a Riemannian manifold. It is a local invariant of Riemannian metrics which measures the failure of the second covariant derivatives to commute. A Riemannian manifold has zero curvature if and only if it is flat, i.e. locally isometric to the Euclidean space. The curvature tensor can also be defined for any pseudo-Riemannian manifold, or indeed any manifold equipped with an affine connection.

In special relativity, a four-vector is an object with four components, which transform in a specific way under Lorentz transformations. Specifically, a four-vector is an element of a four-dimensional vector space considered as a representation space of the standard representation of the Lorentz group, the representation. It differs from a Euclidean vector in how its magnitude is determined. The transformations that preserve this magnitude are the Lorentz transformations, which include spatial rotations and boosts.

In differential geometry, the Einstein tensor is used to express the curvature of a pseudo-Riemannian manifold. In general relativity, it occurs in the Einstein field equations for gravitation that describe spacetime curvature in a manner that is consistent with conservation of energy and momentum.

In differential geometry, the four-gradient $is the four-vector analogue of the gradient from vector calculus.$

In general relativity, a geodesic generalizes the notion of a "straight line" to curved spacetime. Importantly, the world line of a particle free from all external, non-gravitational forces is a particular type of geodesic. In other words, a freely moving or falling particle always moves along a geodesic.

In differential geometry and mathematical physics, a spin connection is a connection on a spinor bundle. It is induced, in a canonical manner, from the affine connection. It can also be regarded as the gauge field generated by local Lorentz transformations. In some canonical formulations of general relativity, a spin connection is defined on spatial slices and can also be regarded as the gauge field generated by local rotations.

A theoretical motivation for general relativity, including the motivation for the geodesic equation and the Einstein field equation, can be obtained from special relativity by examining the dynamics of particles in circular orbits about the Earth. A key advantage in examining circular orbits is that it is possible to know the solution of the Einstein Field Equation a priori. This provides a means to inform and verify the formalism.

Scalar–tensor–vector gravity (STVG) is a modified theory of gravity developed by John Moffat, a researcher at the Perimeter Institute for Theoretical Physics in Waterloo, Ontario. The theory is also often referred to by the acronym MOG.

In physics, Maxwell's equations in curved spacetime govern the dynamics of the electromagnetic field in curved spacetime or where one uses an arbitrary coordinate system. These equations can be viewed as a generalization of the vacuum Maxwell's equations which are normally formulated in the local coordinates of flat spacetime. But because general relativity dictates that the presence of electromagnetic fields induce curvature in spacetime, Maxwell's equations in flat spacetime should be viewed as a convenient approximation.

In the theory of general relativity, a stress–energy–momentum pseudotensor, such as the Landau–Lifshitz pseudotensor, is an extension of the non-gravitational stress–energy tensor that incorporates the energy–momentum of gravity. It allows the energy–momentum of a system of gravitating matter to be defined. In particular it allows the total of matter plus the gravitating energy–momentum to form a conserved current within the framework of general relativity, so that the total energy–momentum crossing the hypersurface of any compact space–time hypervolume vanishes.

The Newman–Penrose (NP) formalism is a set of notation developed by Ezra T. Newman and Roger Penrose for general relativity (GR). Their notation is an effort to treat general relativity in terms of spinor notation, which introduces complex forms of the usual variables used in GR. The NP formalism is itself a special case of the tetrad formalism, where the tensors of the theory are projected onto a complete vector basis at each point in spacetime. Usually this vector basis is chosen to reflect some symmetry of the spacetime, leading to simplified expressions for physical observables. In the case of the NP formalism, the vector basis chosen is a null tetrad: a set of four null vectors—two real, and a complex-conjugate pair. The two real members often asymptotically point radially inward and radially outward, and the formalism is well adapted to treatment of the propagation of radiation in curved spacetime. The Weyl scalars, derived from the Weyl tensor, are often used. In particular, it can be shown that one of these scalars— $in the appropriate frame—encodes the outgoing gravitational radiation of an asymptotically flat system.$

There are various mathematical descriptions of the electromagnetic field that are used in the study of electromagnetism, one of the four fundamental interactions of nature. In this article, several approaches are discussed, although the equations are in terms of electric and magnetic fields, potentials, and charges with currents, generally speaking.

In continuum mechanics, a compatible deformation tensor field in a body is that unique tensor field that is obtained when the body is subjected to a continuous, single-valued, displacement field. Compatibility is the study of the conditions under which such a displacement field can be guaranteed. Compatibility conditions are particular cases of integrability conditions and were first derived for linear elasticity by Barré de Saint-Venant in 1864 and proved rigorously by Beltrami in 1886.

In mathematical physics, the Belinfante–Rosenfeld tensor is a modification of the energy–momentum tensor that is constructed from the canonical energy–momentum tensor and the spin current so as to be symmetric yet still conserved.

Affine gauge theory is classical gauge theory where gauge fields are affine connections on the tangent bundle over a smooth manifold $. For instance, these are gauge theory of dislocations in continuous media when, the generalization of metric-affine gravitation theory when is a world manifold and, in particular, gauge theory of the fifth force.$

Infinite derivative gravity is a theory of gravity which attempts to remove cosmological and black hole singularities by adding extra terms to the Einstein–Hilbert action, which weaken gravity at short distances.

In theoretical physics, the dual graviton is a hypothetical elementary particle that is a dual of the graviton under electric-magnetic duality, as an S-duality, predicted by some formulations of supergravity in eleven dimensions.

This article summarizes several identities in exterior calculus.

References

Aldersley, S. J. (1979). "Comments on certain divergence-free tensor densities in a 3-space". Journal of Mathematical Physics . 20 (9): 1905–1907. Bibcode:1979JMP....20.1905A. doi: 10.1063/1.524289 .
Choquet-Bruhat, Yvonne (2009). General Relativity and the Einstein Equations. Oxford, England: Oxford University Press. ISBN 978-0-19-923072-3.
Cotton, É. (1899). "Sur les variétés à trois dimensions". Annales de la Faculté des Sciences de Toulouse . II. 1 (4): 385–438. Archived from the original on 2007-10-10.
Eisenhart, Luther P. (1977) [1925]. Riemannian Geometry. Princeton, NJ: Princeton University Press. ISBN 0-691-08026-7.
A. Garcia, F.W. Hehl, C. Heinicke, A. Macias (2004) "The Cotton tensor in Riemannian spacetimes", Classical and Quantum Gravity 21: 1099–1118, Eprint arXiv:gr-qc/0309008

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.