Conformal Killing vector field

Last updated December 05, 2024

In conformal geometry, a conformal Killing vector field on a manifold of dimension n with (pseudo) Riemannian metric $g$ (also called a conformal Killing vector, CKV, or conformal colineation), is a vector field $X$ whose (locally defined) flow defines conformal transformations, that is, preserve $g$ up to scale and preserve the conformal structure. Several equivalent formulations, called the conformal Killing equation, exist in terms of the Lie derivative of the flow e.g. ${\mathcal {L}}_{X}g=\lambda g$ for some function $\lambda$ on the manifold. For $n\neq 2$ there are a finite number of solutions, specifying the conformal symmetry of that space, but in two dimensions, there is an infinity of solutions. The name Killing refers to Wilhelm Killing, who first investigated Killing vector fields.

Densitized metric tensor and Conformal Killing vectors

A vector field $X$ is a Killing vector field if and only if its flow preserves the metric tensor $g$ (strictly speaking for each compact subsets of the manifold, the flow need only be defined for finite time). Formulated mathematically, $X$ is Killing if and only if it satisfies

{\mathcal {L}}_{X}g=0.

where ${\mathcal {L}}_{X}$ is the Lie derivative.

More generally, define a w-Killing vector field $X$ as a vector field whose (local) flow preserves the densitized metric $g\mu _{g}^{w}$ , where $\mu _{g}$ is the volume density defined by $g$ (i.e. locally $\mu _{g}={\sqrt {|\det(g)|}}\,dx^{1}\cdots dx^{n}$ ) and $w\in \mathbf {R}$ is its weight. Note that a Killing vector field preserves $\mu _{g}$ and so automatically also satisfies this more general equation. Also note that $w=-2/n$ is the unique weight that makes the combination $g\mu _{g}^{w}$ invariant under scaling of the metric. Therefore, in this case, the condition depends only on the conformal structure. Now $X$ is a w-Killing vector field if and only if

{\mathcal {L}}_{X}\left(g\mu _{g}^{w}\right)=({\mathcal {L}}_{X}g)\mu _{g}^{w}+wg\mu _{g}^{w-1}{\mathcal {L}}_{X}\mu _{g}=0.

Since ${\mathcal {L}}_{X}\mu _{g}=\operatorname {div} (X)\mu _{g}$ this is equivalent to

{\mathcal {L}}_{X}g=-w\operatorname {div} (X)g.

Taking traces of both sides, we conclude $2\mathop {\mathrm {div} } (X)=-wn\operatorname {div} (X)$ . Hence for $w\neq -2/n$ , necessarily $\operatorname {div} (X)=0$ and a w-Killing vector field is just a normal Killing vector field whose flow preserves the metric. However, for $w=-2/n$ , the flow of $X$ has to only preserve the conformal structure and is, by definition, a conformal Killing vector field.

Equivalent formulations

The following are equivalent

$X$ is a conformal Killing vector field,
The (locally defined) flow of $X$ preserves the conformal structure,
${\mathcal {L}}_{X}(g\mu _{g}^{-2/n})=0,$
${\mathcal {L}}_{X}g={\frac {2}{n}}\operatorname {div} (X)g,$
${\mathcal {L}}_{X}g=\lambda g$ for some function $\lambda .$

The discussion above proves the equivalence of all but the seemingly more general last form. However, the last two forms are also equivalent: taking traces shows that necessarily $\lambda =(2/n)\operatorname {div} (X)$ .

The last form makes it clear that any Killing vector is also a conformal Killing vector, with $\lambda \cong 0.$

The conformal Killing equation

Using that ${\mathcal {L}}_{X}g=2\left(\nabla X^{\flat }\right)^{\mathrm {symm} }$ where $\nabla$ is the Levi Civita derivative of $g$ (aka covariant derivative), and $X^{\flat }=g(X,\cdot )$ is the dual 1 form of $X$ (aka associated covariant vector aka vector with lowered indices), and ${}^{\mathrm {symm} }$ is projection on the symmetric part, one can write the conformal Killing equation in abstract index notation as

\nabla _{a}X_{b}+\nabla _{b}X_{a}={\frac {2}{n}}g_{ab}\nabla _{c}X^{c}.

Another index notation to write the conformal Killing equations is

X_{a;b}+X_{b;a}={\frac {2}{n}}g_{ab}X^{c}{}_{;c}.

Examples

Flat space

In $n$ -dimensional flat space, that is Euclidean space or pseudo-Euclidean space, there exist globally flat coordinates in which we have a constant metric $g_{\mu \nu }=\eta _{\mu \nu }$ where in space with signature $(p,q)$ , we have components $(\eta _{\mu \nu })={\text{diag}}(+1,\cdots ,+1,-1,\cdots ,-1)$ . In these coordinates, the connection components vanish, so the covariant derivative is the coordinate derivative. The conformal Killing equation in flat space is $\partial _{\mu }X_{\nu }+\partial _{\nu }X_{\mu }={\frac {2}{n}}\eta _{\mu \nu }\partial _{\rho }X^{\rho }.$ The solutions to the flat space conformal Killing equation includes the solutions to the flat space Killing equation discussed in the article on Killing vector fields. These generate the Poincaré group of isometries of flat space. Considering the ansatz $X^{\mu }=M^{\mu \nu }x_{\nu },$ , we remove the antisymmetric part of $M^{\mu \nu }$ as this corresponds to known solutions, and we're looking for new solutions. Then $M^{\mu \nu }$ is symmetric. It follows that this is a dilatation, with $M_{\nu }^{\mu }=\lambda \delta _{\nu }^{\mu }$ for real $\lambda$ , and corresponding Killing vector $X^{\mu }=\lambda x^{\mu }$ .

From the general solution there are $n$ more generators, known as special conformal transformations, given by

X_{\mu }=c_{\mu \nu \rho }x^{\nu }x^{\rho },

where the traceless part of $c_{\mu \nu \rho }$ over $\mu ,\nu$ vanishes, hence can be parametrised by $c^{\mu }{}_{\mu \nu }=b_{\nu }$ .

General solution to the conformal Killing equation (in more than two dimensions)^[1]
For convenience we rewrite the conformal Killing equation as $\partial _{\mu }X_{\nu }+\partial _{\nu }X_{\mu }=f(\mathbf {x} )g_{\mu \nu }.$ (By taking traces we can recover $f(\mathbf {x} )={\frac {2}{n}}\partial _{\rho }X^{\rho }.$ ) Applying an extra derivative, relabelling indices and taking a linear combination of the resulting equations gives $2\partial _{\mu }\partial _{\nu }X_{\rho }=\eta _{\mu \rho }\partial _{\nu }f+\eta _{\nu \rho }\partial _{\mu }f-\eta _{\mu \nu }\partial _{\rho }f.$ Contracting on $\mu ,\nu$ gives $2\partial ^{2}X_{\rho }=(2-n)\partial _{\rho }f.$ A combination of derivatives of this and the original conformal Killing equation gives $(2-n)\partial _{\mu }\partial _{\nu }f=\eta _{\mu \nu }\partial ^{2}f,$ and contracting gives $(n-1)\partial ^{2}f=0.$ Now focussing on the case $n\geq 3$ , the two previous equations together show $\partial _{\mu }\partial _{\nu }f=0$ , so $f$ is at most linear in the coordinates. Substituting into an earlier equation gives that $\partial _{\mu }\partial _{\nu }X_{\rho }$ is constant, so $X_{\mu }$ is at most quadratic in coordinates, with general form $X_{\mu }=a_{\mu }+b_{\mu \nu }x^{\nu }+c_{\mu \nu \rho }x^{\nu }x^{\rho }.$

Together, the $n$ translations, $n(n-1)/2$ Lorentz transformations, $1$ dilatation and $n$ special conformal transformations comprise the conformal algebra, which generate the conformal group of pseudo-Euclidean space.

Related Research Articles

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. It has become vital in the building of the Standard Model.

The stress–energy tensor, sometimes called the stress–energy–momentum tensor or the energy–momentum tensor, is a tensor physical quantity that describes the density and flux of energy and momentum in spacetime, generalizing the stress tensor of Newtonian physics. It is an attribute of matter, radiation, and non-gravitational force fields. This density and flux of energy and momentum are the sources of the gravitational field in the Einstein field equations of general relativity, just as mass density is the source of such a field in Newtonian gravity.

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 physics and mathematics, the Helmholtz decomposition theorem or the fundamental theorem of vector calculus states that certain differentiable vector fields can be resolved into the sum of an irrotational (curl-free) vector field and a solenoidal (divergence-free) vector field. In physics, often only the decomposition of sufficiently smooth, rapidly decaying vector fields in three dimensions is discussed. It is named after Hermann von Helmholtz.

The Einstein–Hilbert action in general relativity is the action that yields the Einstein field equations through the stationary-action principle. With the (− + + +) metric signature, the gravitational part of the action is given as

In mathematics, a Killing vector field, named after Wilhelm Killing, is a vector field on a Riemannian manifold that preserves the metric. Killing fields are the infinitesimal generators of isometries; that is, flows generated by Killing fields are continuous isometries of the manifold. More simply, the flow generates a symmetry, in the sense that moving each point of an object the same distance in the direction of the Killing vector will not distort distances on the object.

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

When studying and formulating Albert Einstein's theory of general relativity, various mathematical structures and techniques are utilized. The main tools used in this geometrical theory of gravitation are tensor fields defined on a Lorentzian manifold representing spacetime. This article is a general description of the mathematics of general relativity.

In general relativity, specifically in the Einstein field equations, a spacetime is said to be stationary if it admits a Killing vector that is asymptotically timelike.

The covariant formulation of classical electromagnetism refers to ways of writing the laws of classical electromagnetism in a form that is manifestly invariant under Lorentz transformations, in the formalism of special relativity using rectilinear inertial coordinate systems. These expressions both make it simple to prove that the laws of classical electromagnetism take the same form in any inertial coordinate system, and also provide a way to translate the fields and forces from one frame to another. However, this is not as general as Maxwell's equations in curved spacetime or non-rectilinear coordinate systems.

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 conformal geometry, the tractor bundle is a particular vector bundle constructed on a conformal manifold whose fibres form an effective representation of the conformal group.

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— $in the appropriate frame—encodes the outgoing gravitational radiation of an asymptotically flat system.$

In physics, f(R) is a type of modified gravity theory which generalizes Einstein's general relativity. f(R) gravity is actually a family of theories, each one defined by a different function, f, of the Ricci scalar, R. The simplest case is just the function being equal to the scalar; this is general relativity. As a consequence of introducing an arbitrary function, there may be freedom to explain the accelerated expansion and structure formation of the Universe without adding unknown forms of dark energy or dark matter. Some functional forms may be inspired by corrections arising from a quantum theory of gravity. f(R) gravity was first proposed in 1970 by Hans Adolph Buchdahl (although ϕ was used rather than f for the name of the arbitrary function). It has become an active field of research following work by Alexei Starobinsky on cosmic inflation. A wide range of phenomena can be produced from this theory by adopting different functions; however, many functional forms can now be ruled out on observational grounds, or because of pathological theoretical problems.

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

In mathematical physics, the Dirac equation in curved spacetime is a generalization of the Dirac equation from flat spacetime to curved spacetime, a general Lorentzian manifold.

Lagrangian field theory is a formalism in classical field theory. It is the field-theoretic analogue of Lagrangian mechanics. Lagrangian mechanics is used to analyze the motion of a system of discrete particles each with a finite number of degrees of freedom. Lagrangian field theory applies to continua and fields, which have an infinite number of degrees of freedom.

In general relativity and tensor calculus, the Palatini identity is

In theoretical physics, more specifically in quantum field theory and supersymmetry, supersymmetric Yang–Mills, also known as super Yang–Mills and abbreviated to SYM, is a supersymmetric generalization of Yang–Mills theory, which is a gauge theory that plays an important part in the mathematical formulation of forces in particle physics. It is a special case of 4D N = 1 global supersymmetry.

In supersymmetry, 4D $supergravity$ is the theory of supergravity in four dimensions with a single supercharge. It contains exactly one supergravity multiplet, consisting of a graviton and a gravitino, but can also have an arbitrary number of chiral and vector supermultiplets, with supersymmetry imposing stringent constraints on how these can interact. The theory is primarily determined by three functions, those being the Kähler potential, the superpotential, and the gauge kinetic matrix. Many of its properties are strongly linked to the geometry associated to the scalar fields in the chiral multiplets. After the simplest form of this supergravity was first discovered, a theory involving only the supergravity multiplet, the following years saw an effort to incorporate different matter multiplets, with the general action being derived in 1982 by Eugène Cremmer, Sergio Ferrara, Luciano Girardello, and Antonie Van Proeyen.

References

↑ P. Di Francesco, P. Mathieu, and D. Sénéchal, Conformal Field Theory, 1997, ISBN 0-387-94785-X