Difference between revisions of "Transverse traceless gauge"

1) The two algebraic conditions are \begin{align} 0&=u^{\mu}h_{\mu\nu}=h_{0\nu}=(\Phi,-\mathbf{w});\\ 0&=h^{\mu}_{\mu}=\Phi-6\Psi, \end{align} so we get in the new frame \[\Phi=\Psi=0,\quad \mathbf{w}=0.\] Then the remaining Lorenz condition is reduced to \begin{align*} &0=\partial_0 h^0_\nu +\partial_\alpha h^\alpha_\nu ;\\ \nu=0:\quad& 0=0;\\ \nu=\beta:\quad&0= \partial_{\alpha}{s^{\alpha}}_{\beta}, \end{align*} so it takes the form \begin{equation} \partial_{\alpha}{s^{\alpha}}_{\beta}=0. \end{equation} Thus the only remaining non-trivial component of the perturbation is the tensor one (the traceless part) $s_{\alpha\beta}$, and it is transverse, in the sense that for a plane wave solution $s_{\alpha\beta}\sim e^{i\,k_{\mu}x^{\mu}}$ the metric perturbation is transverse with respect to the wave vector: \[k^{\alpha}s_{\alpha\beta}=0.\] 2) Transversality implies $h_{\mu 0}=0$, Lorenz gauge condition that $h_{\mu z}=0$, so the only non-zero components are $h_{xx},h_{yy},h_{xy},h_{yx}$. Of those only two are independent due to symmetry $h_{xy}=h_{yx}$ and tracelessness $h_{xx}+h_{yy}=0$. \end{enumerate}

The two-dimensional transformation matrix $\Phi$ for rotation by $\pi/4$ and the polarization tensors are \[\Phi=(x^{\mu}_{,\nu})=\frac{1}{\sqrt{2}} \begin{pmatrix}1&1\\-1&1 \end{pmatrix},\quad (e^{(+)}_{\mu\nu}) =\begin{pmatrix}1&0\\0&-1\end{pmatrix},\quad (e^{(\times)}_{\mu\nu}) =\begin{pmatrix}0&1\\1&0\end{pmatrix}.\] In matrix notation the second rank tensor transformation law is $e'=\Phi\Phi e$, and acting twice on each of the polarization vectors we have \begin{align*} \Phi\Phi e^{(+)}&=\frac12 \begin{pmatrix}1&1\\-1&1 \end{pmatrix} \begin{pmatrix}1&1\\-1&1 \end{pmatrix} \begin{pmatrix}1&0\\0&-1 \end{pmatrix} =-\begin{pmatrix}0&+1\\1&0 \end{pmatrix} =-e^{(\times)},\\ \Phi\Phi e^{(\times)}&=\frac12 \begin{pmatrix}1&1\\-1&1 \end{pmatrix} \begin{pmatrix}1&1\\-1&1 \end{pmatrix} \begin{pmatrix}0&+1\\1&0 \end{pmatrix} =+\begin{pmatrix}1&0\\0&-1 \end{pmatrix} =+e^{(+)}. \end{align*}

1) The gauge transformation for $\bar{h}_{\mu\nu}$ and therefore $A_{\mu\nu}$ is \[A_{\mu\nu}\to A_{\mu\nu}' =A_{\mu\nu}-2\partial_{(\mu}\xi_{\nu)} +\eta_{\mu\nu}\partial_{\lambda}\xi^\lambda,\] so \begin{equation} A_{\mu\nu}\to A_{\mu\nu}' =A_{\mu\nu}-2ik_{(\mu}B_{\nu)} +i\eta_{\mu\nu}k_{\lambda}B^\lambda, \end{equation} and the TT gauge conditions take the form \begin{align} 0&={{A'}^{\mu}}_{\mu}={A^{\mu}}_{\mu}+2ik^\mu B_\mu;\\ 0&={A'}_{0\;\mu}=A_{0\mu}-ik_0 B_{\mu} -ik_\mu B_0 +i\delta^0_\mu \; k_\lambda B^\lambda. \end{align} Also remember that Lorenz gauge implies $k_{\mu}A^{\mu\nu}=0$, thus $k^{\alpha}A_{\alpha\mu}=-\omega A_{0\mu}$, and therefore \begin{equation} l^{\mu}k_{\mu}=2\omega^2,\quad A_{\mu\nu}l^{\mu}=2\omega A_{0\mu},\quad k^{\lambda}B_{\lambda} =-\frac{1}{2i}{A^{\lambda}}_{\lambda}. \end{equation} Plugging this into the gauge conditions, one can see that the first one (tracelessness) is obeyed immediately, and the second one (transversality) after a little bit of more algebra. 2) The general first-order vacuum solution of Einstein's equations in the Lorenz gauge can be presented through its spatial Fourier transform (temporal part is integrated over due to fixed dispersion relation) \[h_{\mu\nu}(x)=\int d^{3}k h_{\mu\nu}(\mathbf{k}) e^{ik_{\lambda}x^{\lambda}},\quad\text{with}\quad k^\mu k_\mu =0,\quad\Leftrightarrow\quad k_{0}^{2}\equiv \omega^2 =\mathbf{k}^2.\] Then the TT gauge will be fixed by the coordinate fransformation \[\xi^\mu =\int d^{3}k B^{\mu}[h_{\mu\nu}(\mathbf{k})] e^{ik_{\lambda}x^{\lambda}}.\] Working with individual plane-wave solutions is equivalent to working in the full Fourier space. \end{enumerate}

1) The covariant derivatives in the Bianchi identity \[R_{abcd;e}+R_{abec;d}+R_{abde;c}=0\] in the first order can be replaced by partial derivatives. Then for a plane-wave solution \[k_{e}R_{abcd}+k_{d}R_{abec}+k_{c}R_{abde}=0.\] By setting $\{eabcd\}=\{0\alpha 0\beta \gamma\}$ we get ($k_0\equiv \omega \neq 0$ for a null vector) \[R_{\alpha 0\beta \gamma} =-\frac{k_\beta}{\omega}R_{\alpha 0\gamma 0} +\frac{k_\gamma}{\omega}R_{\alpha 0\beta 0},\] and by setting $\{eabcd\}=\{0\alpha \beta \gamma\delta \}$ and using the previous result, that \[R_{\alpha\beta\gamma\delta}= \frac{k_\alpha k_\gamma}{\omega^2} R_{0\beta 0\gamma} +\big(\text{three terms restored by symmetry}\big).\] 2) From vacuum Einstein equations \[0=R^{\lambda \mu\lambda \nu} =R_{0\mu 0\nu}-R_{\alpha\mu\alpha\nu},\] expressing everything through $R_{0\alpha 0\beta}$, we get \begin{align} 00:&\quad R_{0\alpha 0\alpha}=0;\\ 0\beta:&\quad k_{\alpha} R_{0\alpha 0\beta}=0;\\ \beta\gamma:&\quad 0=0. \end{align} The $00$ equation translates to the wave being traceless, and the $0\beta$ equation to it being transverse: in the chosen frame \[R_{0x0x}+R_{0y0y}=0,\qquad R_{0z0\alpha}=0.\] 3) In the TT gauge $g_{00}$ and $g_{0\alpha}$ are zero, so in the first order \[R_{0\alpha 0\beta}=\frac{1}{2}\big( \partial_0 \partial_\beta g_{0\alpha} +\partial_\alpha \partial_0 g_{0\beta} -\partial_0 \partial_0 g_{\alpha\beta} -\partial_\alpha \partial_\beta g_{00}\big) =-\tfrac12 \partial_0^2 g_{\alpha\beta}.\] As the curvature tensor is gauge invariant, the last relation allows one to calculate the metric components in the TT gauge $g_{\alpha\beta}^{TT}$ without the prior gauge fixing.