Tetrad (index notation)

In Riemannian geometry, we can introduce a coordinate system over the Riemannian manifold (at least, over a chart), giving n coordinates

x_{i}\;\text{,}\qquad i = 1, \dots, n

for an n-dimensional manifold. Locally, at least, this gives a basis for the 1-forms, dxⁱ where d is the exterior derivative. The dual basis for the tangent space T is e_i.

Now, let's choose an orthonormal basis for the fibers of T. The rest is index manipulation.

Example

Take a 3-sphere with the radius R and give it polar coordinates α, θ, φ.

e(e_α)/R,

e(e_θ)/R sin(α) and

e(e_φ)/R sin(α) sin(θ)

form an orthonormal basis of T.

Call these e₁, e₂ and e₃. Given the metric η, we can ignore the covariant and contravariant distinction for T.

Then, the dreibein (triad),

e_1 = R\, d\alpha

e_2 = R\, \sin{(\alpha)} d\theta

e_3 = R\, \sin{(\alpha)} \sin{(\theta)} d\phi

.

So,

de_1=0

de_2=R \cos{(\alpha)} d\alpha \wedge d\theta

de_3=R (\cos{(\alpha)} \sin{(\theta)} d\alpha \wedge d\phi + \sin{(\alpha)} \cos{(\theta)} d\theta \wedge d\phi)

.

from the relation

d_\mathbf{A} e = de + A \wedge e = 0

,

we get

A_{12} = -\cos{(\alpha)} \, d\theta

A_{13} = -\cos{(\alpha)} \, \sin{(\theta)} d\phi

A_{23} = -\cos{(\theta)} \, d\phi

.

(d_Aη=0 tells us A is antisymmetric)

So, $\mathbf{F} = d\mathbf{A} + \mathbf{A} \wedge \mathbf{A}$ ,

F_{12}=\sin{(\alpha)} d\alpha\wedge d\theta

F_{13}=\sin{(\alpha)} \sin{(\theta)} d\alpha\wedge d\phi

F_{23}=\sin^2{(\alpha)} \sin{(\theta)} d\theta\wedge d\phi

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Tetrad (index notation)

Example

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