The tetrad formalism is an approach to general relativity that generalizes the choice of basis for the tangent bundle from a coordinate basis to the less restrictive choice of a local basis, i.e. a locally defined set of four linearly independent vector fields called a tetrad or vierbein. It is a special case of the more general idea of a vielbein formalism, which is set in (pseudo-)Riemannian geometry. This article as currently written makes frequent mention of general relativity; however, almost everything it says is equally applicable to (pseudo-)Riemannian manifolds in general, and even to spin manifolds. Most statements hold simply by substituting arbitrary
n
n=4
The general idea is to write the metric tensor as the product of two vielbeins, one on the left, and one on the right. The effect of the vielbeins is to change the coordinate system used on the tangent manifold to one that is simpler or more suitable for calculations. It is frequently the case that the vielbein coordinate system is orthonormal, as that is generally the easiest to use. Most tensors become simple or even trivial in this coordinate system; thus the complexity of most expressions is revealed to be an artifact of the choice of coordinates, rather than a innate property or physical effect. That is, as a formalism, it does not alter predictions; it is rather a calculational technique.
The advantage of the tetrad formalism over the standard coordinate-based approach to general relativity lies in the ability to choose the tetrad basis to reflect important physical aspects of the spacetime. The abstract index notation denotes tensors as if they were represented by their coefficients with respect to a fixed local tetrad. Compared to a completely coordinate free notation, which is often conceptually clearer, it allows an easy and computationally explicit way to denote contractions.
The significance of the tetradic formalism appear in the Einstein–Cartan formulation of general relativity. The tetradic formalism of the theory is more fundamental than its metric formulation as one can not convert between the tetradic and metric formulations of the fermionic actions despite this being possible for bosonic actions . This is effectively because Weyl spinors can be very naturally defined on a Riemannian manifold and their natural setting leads to the spin connection. Those spinors take form in the vielbein coordinate system, and not in the manifold coordinate system.
The privileged tetradic formalism also appears in the deconstruction of higher dimensional Kaluza–Klein gravity theories[1] and massive gravity theories, in which the extra-dimension(s) is/are replaced by series of N lattice sites such that the higher dimensional metric is replaced by a set of interacting metrics that depend only on the 4D components.[2] Vielbeins commonly appear in other general settings in physics and mathematics. Vielbeins can be understood as solder forms.
The tetrad formulation is a special case of a more general formulation, known as the vielbein or -bein formulation, with =4. Make note of the spelling: in German, "viel" means "many", not to be confused with "vier", meaning "four".
In the vielbein formalism,[3] an open cover of the spacetime manifold
M
n
ea=
| \mu | |
| e | |
| a{} |
\partial\mu
a=1,\ldots,n
n
n
ea=
| a{} | |
| e | |
| \mu |
dx\mu
ea(eb)=
| a{} | |
| e | |
| \mu |
| \mu | |
| e | |
| b{} |
=
| a | |
| \delta | |
| b |
,
| a | |
| \delta | |
| b |
| \mu{} | |
| e | |
| a |
x\mu
From the point of view of the differential geometry of fiber bundles, the vector fields
\{ea\}a=1...
U\subsetM
TU\congU x {Rn}
U
M
All tensors of the theory can be expressed in the vector and covector basis, by expressing them as linear combinations of members of the (co)vielbein. For example, the spacetime metric tensor can be transformed from a coordinate basis to the tetrad basis.
Popular tetrad bases in general relativity include orthonormal tetrads and null tetrads. Null tetrads are composed of four null vectors, so are used frequently in problems dealing with radiation, and are the basis of the Newman–Penrose formalism and the GHP formalism.
The standard formalism of differential geometry (and general relativity) consists simply of using the coordinate tetrad in the tetrad formalism. The coordinate tetrad is the canonical set of vectors associated with the coordinate chart. The coordinate tetrad is commonly denoted
\{\partial\mu\}
\{dx\mu\}
{\varphi=(\varphi1,\ldots,\varphin)}
Rn
f
\partial\mu[f]\equiv
| \partial(f\circ\varphi-1) | |
| \partialx\mu |
.
dx\mu=d\varphi\mu
M
⊗
gab
Changing tetrads is a routine operation in the standard formalism, as it is involved in every coordinate transformation (i.e., changing from one coordinate tetrad basis to another). Switching between multiple coordinate charts is necessary because, except in trivial cases, it is not possible for a single coordinate chart to cover the entire manifold. Changing to and between general tetrads is much similar and equally necessary (except for parallelizable manifolds). Any tensor can locally be written in terms of this coordinate tetrad or a general (co)tetrad.
g
g=g\mu\nudx\mudx\nu where~g\mu\nu=g(\partial\mu,\partial\nu).
(Here we use the Einstein summation convention). Likewise, the metric can be expressed with respect to an arbitrary (co)tetrad as
g=gabeaeb where~gab=g\left(ea,eb\right).
Here, we use choice of alphabet (Latin and Greek) for the index variables to distinguish the applicable basis.
We can translate from a general co-tetrad to the coordinate co-tetrad by expanding the covector
ea=
| a{} | |
| e | |
| \mu |
dx\mu
g=gabeaeb=gab
| a{} | |
| e | |
| \mu |
| b{} | |
| e | |
| \nu |
dx\mudx\nu=g\mu\nudx\mudx\nu
from which it follows that
g\mu\nu=gab
| a{} | |
| e | |
| \mu |
| b{} | |
| e | |
| \nu |
dx\mu=
| \mu{} | |
| e | |
| a |
ea
g=g\mu\nudx\mudx\nu=g\mu
| \mu{} | |
| e | |
| a |
| \nu{} | |
| e | |
| b |
eaeb=gabeaeb
which shows that
gab=g\mu\nu
| \mu{} | |
| e | |
| a |
| \nu{} | |
| e | |
| b |
The manipulation with tetrad coefficients shows that abstract index formulas can, in principle, be obtained from tensor formulas with respect to a coordinate tetrad by "replacing greek by latin indices". However care must be taken that a coordinate tetrad formula defines a genuine tensor when differentiation is involved. Since the coordinate vector fields have vanishing Lie bracket (i.e. commute:
\partial\mu\partial\nu=\partial\nu\partial\mu
[ea,eb]\ne0
For example, the Riemann curvature tensor is defined for general vector fields
X,Y
R(X,Y)=\left(\nablaX\nablaY-\nablaY\nablaX-\nabla[X,Y]\right)
In a coordinate tetrad this gives tensor coefficients
| \mu | |
| R | |
| \nu\sigma\tau |
=
| \mu\left((\nabla | |
| dx | |
| \sigma\nabla |
\tau-\nabla\tau\nabla\sigma)\partial\nu\right).
The naive "Greek to Latin" substitution of the latter expression
| a | |
| R | |
| bcd |
=
| a\left((\nabla | |
| e | |
| c\nabla |
d-\nablad\nablac)eb\right) (wrong!)
\left(\nablac\nablad-\nablad\nablac\right)
| a | |
| R | |
| bcd |
=
| a\left((\nabla | |
| e | |
| c\nabla |
d-\nablad\nablac-fcd{}e\nablae)eb\right)
where
[ea,eb]=fab{}cec
\left(\nablac\nablad-\nablad\nablac-fcd{}e\nablae\right)
Given a vector (or covector) in the tangent (or cotangent) manifold, the exponential map describes the corresponding geodesic of that tangent vector. Writing
X\inTM
e-XdeX=dX-
| 1 | \left[X,dX\right]+ | |
| 2! |
| 1 | [X,[X,dX]]- | |
| 3! |
| 1 | |
| 4! |
[X,[X,[X,dX]]]+ …
X
For the special case of a Lie algebra, the
X
ei
| ie | |
| X=X | |
| i |
Xi,
e-XdeX=dXi
| e | ||||
|
XidXj{fij
[ei,ej]={fij
e-XdeX=
| i} | |
| e | |
| j |
dXj
| infty | |
| W=\sum | |
| n=0 |
| (-1)nMn | |
| (n+1)! |
=(I-e-M)M-1.
M
| k | |
| {M | |
| j} |
=
| i{f | |
| X | |
| ij |
W
dXj
ei
Given some map
N\toG
N
G
N
Bmn
G
gij=
| m | |
| {W | |
| i} |
Bmn
| n} | |
| {W | |
| j |
Bmn
N