One popular metric, used in the study of
mass inflation, is :ds^2 = g_{\mu\nu} dx^\mu dx^\nu = - \frac{dt^2}{\alpha^2} +\frac{1}{\beta_r^2}\left(dr-\beta_t\frac{dt}{\alpha} \right)^2 + r^2\, g(\Omega). Here, g(\Omega) is the standard metric on the unit radius 2-sphere \Omega = (\theta, \phi). The radial coordinate r is defined so that it is the circumferential radius, that is, so that the proper circumference at radius r is 2\pi r. In this coordinate choice, the parameter \beta_t is defined so that \beta_t=dr/d\tau is the proper rate of change of the circumferential radius (that is, where \tau is the
proper time). The parameter \beta_r can be interpreted as the radial derivative of the circumferential radius in a freely-falling frame; this becomes explicit in the
tetrad formalism.
Orthonormal tetrad formalism Note that the above metric is written as a sum of squares, and therefore it can be understood as explicitly encoding a
vierbein, and, in particular, an
orthonormal tetrad. That is, the metric tensor can be written as a
pullback of the
Minkowski metric \eta_{ij}: :g_{\mu\nu} = \eta_{ij} \, e^i_{\;\mu} \, e^j_{\;\nu} where the e^i_{\;\mu} is the inverse vierbein. The convention here and in what follows is that the roman indexes refer to the flat orthonormal tetrad frame, while the greek indexes refer to the coordinate frame. The inverse vierbein can be directly read off of the above metric as :e^t_{\;\mu} dx^\mu=\frac{dt}{\alpha} :e^r_{\;\mu} dx^\mu=\frac{1}{\beta_r}\left(dr-\beta_t\frac{dt}{\alpha} \right) :e^\theta_{\;\mu} dx^\mu=r d\theta :e^\phi_{\;\mu} dx^\mu=r\sin\theta d\phi where the signature was take to be (-+++). Written as a matrix, the inverse vierbein is :e^i_{\;\mu}=\begin{bmatrix} \frac{1}{\alpha} & 0 & 0 & 0 \\ -\frac{\beta_t}{\alpha\beta_r} & \frac{1}{\beta_r} & 0 & 0 \\ 0 & 0 & r & 0 \\ 0 & 0 & 0 & r\sin \theta \\ \end{bmatrix} The vierbein itself is the inverse(-transpose) of the inverse vierbein :e_i^{\;\mu}=\begin{bmatrix} \alpha & \beta_t & 0 & 0 \\ 0 & \beta_r & 0 & 0 \\ 0 & 0 & \frac{1}{r} & 0 \\ 0 & 0 & 0 & \frac{1}{r\sin \theta} \\ \end{bmatrix} That is, (e^i_{\;\mu})^T e_i^{\;\nu}=e_\mu^{\;\;i} e_i^{\;\nu}=\delta^\nu_\mu is the identity matrix. The particularly simple form of the above is a prime motivating factor for working with the given metric. The vierbein relates vector fields in the coordinate frame to vector fields in the tetrad frame, as :\partial_i=e_i^{\;\mu}\frac {\partial\;\;}{\partial x^\mu} The most interesting of these two are \partial_t which is the proper time in the rest frame, and \partial_r which is the radial derivative in the rest frame. By construction, as noted earlier, \beta_t was the proper rate of change of the circumferential radius; this can now be explicitly written as :\beta_t=\partial_t r Similarly, one has :\beta_r=\partial_r r which describes the gradient (in the free-falling tetrad frame) of the circumferential radius along the radial direction. This is not in general unity; compare, for example, to the standard Swarschild solution, or the Reissner–Nordström solution. The sign of \beta_r effectively determines "which way is down"; the sign of \beta_r distinguishes incoming and outgoing frames, so that \beta_r>0 is an ingoing frame, and \beta_r is an outgoing frame. These two relations on the circumferential radius provide another reason why this particular parameterization of the metric is convenient: it has a simple intuitive characterization.
Connection form The
connection form in the tetrad frame can be written in terms of the
Christoffel symbols \Gamma_{ijk} in the tetrad frame, which are given by :\Gamma_{rtt} = -\partial_r\ln\alpha :\Gamma_{rtr} = -\beta_t\frac{\partial\ln\alpha}{\partial r} + \frac{\partial\beta_t}{\partial r}-\partial_t\ln\beta_r :\Gamma_{\theta t\theta} = \Gamma_{\phi t\phi} = \frac{\beta_t}{r} :\Gamma_{\theta r\theta} = \Gamma_{\phi r\phi} = \frac{\beta_r}{r} :\Gamma_{\phi\theta\phi} = \frac{\cot\theta}{r} and all others zero.
Einstein equations A complete set of expressions for the
Riemann tensor, the
Einstein tensor and the
Weyl curvature scalar can be found in Hamilton & Avelino. The Einstein equations become :\nabla_t\beta_t=-\frac{M}{r^2}-4\pi rp :\nabla_t\beta_r=4\pi rf where \nabla_t is the covariant time derivative (and \nabla the
Levi-Civita connection), p the radial pressure (
not the isotropic pressure!), and f the radial energy flux. The mass M(r) is the
Misner-Thorne mass or
interior mass, given by :\frac{2M}{r}-1=\beta_t^2-\beta_r^2 As these equations are effectively two-dimensional, they can be solved without overwhelming difficulty for a variety of assumptions about the nature of the infalling material (that is, for the assumption of a spherically symmetric black hole that is accreting charged or neutral dust, gas, plasma or dark matter, of high or low temperature,
i.e. material with various
equations of state.) == See also ==