Petrov classification
In differential geometry and theoretical physics, the Petrov classification describes the possible algebraic symmetries of the Weyl tensor at each event in a Lorentzian manifold.
It is most often applied in studying exact solutions of Einstein's field equations, but strictly speaking the classification is a theorem in pure mathematics applying to any Lorentzian manifold, independent of any physical interpretation. The classification was found in 1954 by A. Z. Petrov and independently by Felix Pirani in 1957.
Classification theorem
We can think of a fourth rank tensor such as the Weyl tensor, evaluated at some event, as acting on the space of bivectors at that event like a linear operator acting on a vector space:Then, it is natural to consider the problem of finding eigenvalues and eigenvectors such that
In Lorentzian spacetimes, there is a six-dimensional space of antisymmetric bivectors at each event. However, the symmetries of the Weyl tensor imply that any eigenbivectors must belong to a four-dimensional subset.
Thus, the Weyl tensor can in fact have at most four linearly independent eigenbivectors.
Just as in the theory of the eigenvectors of an ordinary linear operator, the eigenbivectors of the Weyl tensor can occur with various multiplicities. Just as in the case of ordinary linear operators, any multiplicities among the eigenbivectors indicates a kind of algebraic symmetry of the Weyl tensor at the given event. Just as you would expect from the theory of the eigenvalues of an ordinary linear operator on a four-dimensional vector space, the different types of Weyl tensor can be determined by solving a characteristic equation, in this case a quartic equation.
These eigenbivectors are associated with certain null vectors in the original spacetime, which are called the principal null directions.
The relevant multilinear algebra is somewhat involved, but the resulting classification theorem states that there are precisely six possible types of algebraic symmetry. These are known as the Petrov types:
- Type I: four simple principal null directions,
- Type II: one double and two simple principal null directions,
- Type D: two double principal null directions,
- Type III: one triple and one simple principal null direction,
- Type N: one quadruple principal null direction,
- Type O: the Weyl tensor vanishes.
Different events in a given spacetime can have different Petrov types. A Weyl tensor that has type I is called algebraically general; otherwise, it is called algebraically special. In General Relativity, type O spacetimes are conformally flat.
Newman–Penrose formalism
The Newman–Penrose formalism is often used in practice for the classification. Consider the following set of bivectors:The Weyl tensor can be expressed as a combination of these bivectors through
where the are the Weyl scalars and c.c. is the complex conjugate. The six different Petrov types are distinguished by which of the Weyl scalars vanish. The conditions are
- Type I :,
- Type II :,
- Type D :,
- Type III :,
- Type N :,
- Type O :.
Bel criteria
- is type N if and only if there exists a vector satisfying
- If is not type N, then is of type III if and only if there exists a vector satisfying
- is of type II if and only if there exists a vector satisfying
- is of type D if and only if there exists two linearly independent vectors, satisfying the conditions
where is the dual of the Weyl tensor at.
In fact, for each criterion above, there are equivalent conditions for the Weyl tensor to have that type. These equivalent conditions are stated in terms of the dual and self-dual of the Weyl tensor and certain bivectors and are collected together in Hall.
The Bel criteria find application in general relativity where determining the Petrov type of algebraically special Weyl tensors is accomplished by searching for null vectors.
Physical interpretation
According to general relativity, the various algebraically special Petrov types have some interesting physical interpretations, the classification then sometimes being called the classification of gravitational fields.Type D regions are associated with the gravitational fields of isolated massive objects, such as stars. More precisely, type D fields occur as the field of a gravitating object which is completely characterized by its mass and angular momentum. The two double principal null directions define "radially" ingoing and outgoing null congruences near the object which is the source of the field.
The electrogravitic tensor in a type D region is very closely analogous to the gravitational fields which are described in Newtonian gravity by a Coulomb type gravitational potential. Such a tidal field is characterized by tension in one direction and compression in the orthogonal directions; the eigenvalues have the pattern. For example, a spacecraft orbiting the Earth experiences a tiny tension along a radius from the center of the Earth, and a tiny compression in the orthogonal directions. Just as in Newtonian gravitation, this tidal field typically decays like, where is the distance from the object.
If the object is rotating about some axis, in addition to the tidal effects, there will be various gravitomagnetic effects, such as spin-spin forces on gyroscopes carried by an observer. In the Kerr vacuum, which is the best known example of type D vacuum solution, this part of the field decays like.
Type III regions are associated with a kind of longitudinal gravitational radiation. In such regions, the tidal forces have a shearing effect. This possibility is often neglected, in part because the gravitational radiation which arises in weak-field theory is type N, and in part because type III radiation decays like, which is faster than type N radiation.
Type N regions are associated with transverse gravitational radiation, which is the type astronomers have detected with LIGO.
The quadruple principal null direction corresponds to the wave vector describing the direction of propagation of this radiation. It typically decays like, so the long-range radiation field is type N.
Type II regions combine the effects noted above for types D, III, and N, in a rather complicated nonlinear way.
Type O regions, or conformally flat regions, are associated with places where the Weyl tensor vanishes identically. In this case, the curvature is said to be pure Ricci. In a conformally flat region, any gravitational effects must be due to the immediate presence of matter or the field energy of some nongravitational field. In a sense, this means that any distant objects are not exerting any long range influence on events in our region. More precisely, if there are any time varying gravitational fields in distant regions, the news has not yet reached our conformally flat region.
Gravitational radiation emitted from an isolated system will usually not be algebraically special.
The peeling theorem describes the way in which, as one moves farther way from the source of the radiation, the various components of the radiation field "peel" off, until finally only type N radiation is noticeable at large distances. This is similar to the electromagnetic peeling theorem.
Examples
In some familiar solutions, the Weyl tensor has the same Petrov type at each event:- the Kerr vacuum is everywhere type D,
- certain Robinson/Trautman vacuums are everywhere type III,
- the pp-wave spacetimes are everywhere type N,
- the FLRW models are everywhere type O.
Some classes of solutions can be invariantly characterized using algebraic symmetries of the Weyl tensor: for example, the class of non-conformally flat null electrovacuum or null dust solutions admitting an expanding but nontwisting null congruence is precisely the class of Robinson/Trautmann spacetimes. These are usually type II, but include type III and type N examples.
Generalization to higher dimensions
A. Coley, R. Milson, V. Pravda and A. Pravdová developed a generalization of algebraic classification to arbitrary spacetime dimension. Their approach uses a null frame basis approach, that is a frame basis containing two null vectors and, along with spacelike vectors. Frame basis components of the Weyl tensor are classified by their transformation properties under local Lorentz boosts. If particular Weyl components vanish, then and/or are said to be Weyl-Aligned Null Directions. In four dimensions, is a WAND if and only if it is a principal null direction in the sense defined above. This approach gives a natural higher-dimensional extension of each of the various algebraic types II,D etc. defined above.An alternative, but inequivalent, generalization was previously defined by de Smet, based on a spinorial approach. However, de Smet's approach is restricted to 5 dimensions only.