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In [[cosmological perturbation theory]], the '''scalar-vector-tensor decomposition''' is a decomposition of the most general linearized [[perturbation]]s of the [[Friedmann-Robertson-Walker metric]] into components according to their transformations under spatial rotations. It was first discovered by [[E. M. Lifshitz]] in 1946. The general metric perturbation has ten degrees of freedom. The decomposition states that the evolution equations for the most general linearized [[perturbation]]s of the [[Friedmann-Robertson-Walker metric]] can be decomposed into four scalars,
:<math>S^{||}_{ij}=(\nabla_i\nabla_j-\frac{1}{3}\delta_{ij}\nabla^2)\phi</math>,▼
:<math>
:<math>h_{0i}=w_i</math>
where <math>S^\perp_i</math> is a spatial vector with <math>\delta^{ij}\nabla_iS_j^\perp=0</math>. This leaves only two independent components of <math>S_{ij}</math>, corresponding to the two [[polarization]]s of [[gravitational wave]]s. The advantage of this formulation is that the scalar, vector and tensor evolution equations are decoupled. In [[representation theory]], this corresponds to decomposing perturbations under the group of [[rotation group|spatial rotation]]s. Two scalar components can further be eliminated by [[gauge transformation]]s, and the vector components are generally ignored, as there are few known physical processes in which they can be generated. As indicated above, the tensor components correspond to gravitational waves.▼
:<math>h_{ij}=2(\phi g_{ij}+S_{ij})</math>
where the Latin indices ''i'' and ''j'' run over spatial components (1,…,3). The tensor field <math>S_{ij}</math> is traceless under the spatial part of the background metric <math>g_{ij}</math> (''i.e.'' <math>g^{ij}S_{ij}=0</math>). The spatial vector <math>w_i</math> and tensor <math>S_{ij}</math> undergo further decomposition. The vector is written
:<math>w_i=w^{||}{}_i+w^{\perp}{}_i,</math>
where <math>\nabla\times\mathbf{w}^{||}=\mathbf{0}</math> and <math>\nabla\cdot\mathbf{w}^{\perp}=0</math> (<math>\nabla_i</math> is the [[covariant derivative]] defined with respect to the spatial metric <math>g_{ij}</math>). The notation is used because in [[Fourier space]], these equations indicate that the vector points parallel and perpendicular to the direction of the wavevector, respectively. The parallel component can be expressed as the gradient of a scalar, <math>w^{||}{}_i=\nabla_iA</math>. Thus <math>\mathbf{w}</math> can be written as a combination of a scalar and a divergenceless, two-component vector.
Finally, an analagous decomposition can be performed on the traceless tensor field <math>S_{ij}</math>. It can be written
:<math>S_{ij}=S^{||}{}_{ij}+S^{\perp}_{ij}+S^T{}_{ij},</math>
where
where <math>B</math> is a scalar (the combination of derivatives is set by the condition that <math>S</math> be traceless), and
:<math>S^\perp{}_{ij}=\nabla_iS^\perp{}_j+\nabla_jS^\perp{}_i</math>,
where <math>S^\perp{}_i</math> is a divergenceless spatial vector. This leaves only two independent components of <math>S^T{}_{ij}</math>, corresponding to the two [[polarization]]s of [[gravitational wave]]s. (Since the graviton is massless, the two polarizations are orthogonal to the direction of propagation, just like the photon.)
▲
==Reference==
*{{cite journal | author = E. Bertschinger | title = Cosmological perturbation theory and structure formation | url = http://arxiv.org/abs/astro-ph/0101009 | year = 2001}}
*E. M. Lifshitz, ''J. Phys. USSR'' '''10''', 116 (1946).
[[Category:Cosmology]]
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