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The Newtonian description of gravity can be formulated in terms of a potential function $\phi$ whose partial derivatives give the acceleration:

$$\frac{d^2\vec{x}}{dt^2}=\vec{g}=-\vec{\nabla}\phi(x)=\left(\frac{\partial\phi}{\partial x}\hat{x}+\frac{\partial\phi}{\partial y}\hat{y}+\frac{\partial\phi}{\partial z}\hat{z}\right).$$

However, in general relativity, we describe gravity by means of the metric. This description is radically different from the Newtonian one, and I don't see how we can recover the latter from the former. Could someone explain how we can obtain the Newtonian potential from general relativity, starting from the metric $g_{\mu\nu}$?

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Since general relativity is supposed to be a theory that supersedes Newtonian gravity, one certainly expects that it can reproduce the results of Newtonian gravity. However, it is only reasonable to expect such a thing to happen in an appropriate limit. Since general relativity is able to describe a large class of situations that Newtonian gravity cannot, it is not reasonable to expect to recover a Newtonian description for arbitrary spacetimes.

However, under suitable assumptions, one does recover the Newtonian description of matter. This is called taking the Newtonian limit (for obvious reasons). In fact, it was used by Einstein himself to fix the constants that appear in the Einstein Field equations (note that I will be setting $c\equiv 1$ throughout).

$$R_{\mu\nu}-\frac{1}{2}g_{\mu\nu}R=\kappa T_{\mu\nu} $$

Requiring that general relativity reproduces Newtonian gravity in the appropriate limit uniquely fixes the constant $\kappa\equiv 8\pi G$. This procedure is described in most (introductory) books on general relativity, too. Now, let us see how to obtain the Newtonian potential from the metric.

Defining the Newtonian limit

We first need to establish in what situation we would expect to recover the Newtonian equation of motion for a particle. First of all, it is clear that we should require that the particle under consideration moves at velocities with magnitudes far below the speed of light. In equations, this is formalized by requiring

$$\frac{\mathrm{d}x^i}{\mathrm{d}\tau}\ll \frac{\mathrm{d}x^0}{\mathrm{d}\tau} \tag{1}$$

where the spacetime coordinates of the particle are $x^\mu=(x^0,x^i)$ and $\tau$ is the proper time. Secondly, we have to consider situation where the gravitational field is "not too crazy", which in any case means that it should not be changing too quickly. We will make more precise as

$$\partial_0 g_{\mu\nu}=0\tag{2}$$

i.e. the metric is stationary. Furthermore we will require that the gravitational field is weak to ensure that we stay in the Newtonian regime. This means that the metric is "almost flat", that is: $g_{\mu\nu}=\eta_{\mu\nu}+h_{\mu\nu}$ where $h_{\mu\nu}$ is a small perturbation, and $\eta_{\mu\nu}:=\operatorname{diag}(-1,1,1,1)$ is the Minkowski metric. The condition $g_{\mu\nu}g^{\nu\rho}=\delta^\rho_\mu$ implies that $g^{\mu\nu}=\eta^{\mu\nu}-h^{\mu\nu}$, to first order in $h$, where we have defined $h^{\mu\nu}:=\eta^{\mu\rho}\eta^{\nu\sigma}h_{\rho\sigma}$$^1$. This can be easily checked by "plug-and-chug".

Taking the Newtonian limit

Now, if we want to recover the equation of motion of a particle, we should look at the corresponding equation in general relativity. That is the geodesic equation

$$\frac{\mathrm{d}^2x^\mu}{\mathrm{d}\tau^2}+\Gamma^\mu_{\nu\rho}\frac{\mathrm{d}x^\nu}{\mathrm{d}\tau}\frac{\mathrm{d}x^\rho}{\mathrm{d}\tau}=0 $$

Now, all we need to do is use our assumptions. First, we use equation $(1)$ and see that only the $00$-component of the second term contributes. We obtain

$$\frac{\mathrm{d}^2x^\mu}{\mathrm{d}\tau^2}+\Gamma^\mu_{00}\frac{\mathrm{d}x^0}{\mathrm{d}\tau}\frac{\mathrm{d}x^0}{\mathrm{d}\tau}=0 $$

From the definition of the Christoffel symbols

$$\Gamma^{\mu}_{\nu\rho}:=\frac{1}{2}g^{\mu\sigma}(\partial_{\nu}g_{\rho\sigma}+\partial_\rho g_{\nu\sigma}-\partial_\sigma g_{\nu\rho}) $$

we see that, after we use equation $(2)$, the only relevant symbols are

$$\Gamma^{\mu}_{00}=-\frac{1}{2}g^{\mu\sigma}\partial_\sigma g_{00} \textrm{.}$$

Using the weak field assumption and keeping only terms to first order in $h$, we obtain from straightforward algebra that

$$\Gamma^{\mu}_{00}=-\frac{1}{2}\eta^{\mu\sigma}\partial_\sigma h_{00} $$

which leaves us with the simplified geodesic equation

$$\frac{\mathrm{d}^2 x^\mu}{\mathrm{d}\tau^2}=\frac{1}{2}\eta^{\mu\sigma}\partial_\sigma h_{00}\bigg(\frac{\mathrm{d}x^0}{\mathrm{d}\tau}\bigg)^2 $$

Once again using equation $(2)$ shows that the $0$-component of this equation just reads $\ddot{x}^0=0$ (where the dot denotes differentiation with respect to $\tau$), so we're left with the non-trivial, spatial components only:

$$\ddot{x}^i=\frac{1}{2}\partial_i h_{00} $$

which looks suspiciously much like the Newtonian equation of motion

$$\ddot{x}^i=-\partial_i\phi$$

After the natural identification $h_{00}=-2\phi$, we see that they are exactly the same. Thus, we obtain $g_{00}=-1-2\phi$, and have expressed the Newtonian potential in terms of the metric.


  1. For a quick 'n' dirty derivation, we assume an expansion of the form $g^{\mu\nu}=\eta^{\mu\nu}+\alpha \eta^{\mu\rho}\eta^{\nu\sigma}h_{\rho\sigma}+\mathcal{O}(h^2)$ (note that the multiplication by $\eta$'s is the only possible thing we can do without getting a second order term), and simply plugging it into the relationship given in the post:

$$(\eta_{\mu\nu}+h_{\mu\nu})\big(\eta^{\mu\nu}+\alpha \eta^{\mu\rho}\eta^{\nu\sigma}h_{\rho\sigma}+\mathcal{O}(h^2)\big)=\delta^\mu_\rho \Leftrightarrow \alpha=-1$$

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  • $\begingroup$ "In fact, it was used by Einstein himself to fix the constants that appear in the Einstein Field equations ...". Does that mean that without Newton's theory the constant $\kappa$ in Einstein's field equations could not be determined? Einstein called his theory a "principle" theory in contrary to Newton's one, which he named a "constructive" theory. There should be no dependece between them if I have understood it right. $\endgroup$
    – JanG
    Commented Jun 15, 2022 at 14:42
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    $\begingroup$ @JanGogolin There is no dependence between Newtonian gravity and general relativity. Both theories contain a single physical free parameter - $\kappa$ in GR and $G$ in Newtonian gravitation - that must be fixed experimentally. This derivation shows that the identification $\kappa = 8 \pi G$ makes the theories match up in the nonrelativistic limit. $\endgroup$
    – tparker
    Commented Jan 18, 2023 at 20:21
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    $\begingroup$ @JanGogolin In some sense, the fact that Einstein's equations are usually formulated in terms of $G$ just reflects the accident of history that Newton's law was discovered first. One could imagine a world in which sentient beings were highly relativistic, and Einstein's field equations were recovered first. In that case, $\kappa$ would be the natural physical quantity that quantifies the strength of gravity. One could imagine that in that world, there would be a non-relativistic regime that's sometimes used to simplify equations, in which Newton's law is formulated in terms of $\kappa/(8 \pi)$ $\endgroup$
    – tparker
    Commented Jan 18, 2023 at 20:24
  • $\begingroup$ @tparker I agree with both your comments. However, to fix $\kappa$ one needs the ultra-relativistic regime with the existence of "maximal force" $~c^4/G$, which can be then experimentally measured. If you like see physics.stackexchange.com/a/726467/281096, my comment there and my another link. $\endgroup$
    – JanG
    Commented Jan 19, 2023 at 11:55
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Danu's answer is wonderfully written. Just to add a little bit more on the very last part of Danu's answer on the natural identification that $h_{00}=-2\phi$. The full metric in the Newtonian limit can in fact be easily calculated using the linearised Einstein Equations and through the same calculation, you can even obtain an expression for $\phi$ that agrees with the usual Newtonian calculation.

The linearised Einstein Equations (in the de Donder gauge) can be written as

$$ \square h _ { \mu \nu } - \frac { 1 } { 2 } \square h \eta _ { \mu \nu } = - 16 \pi G T _ { \mu \nu } $$

and defining $\bar { h } _ { \mu \nu } = h _ { \mu \nu } - \frac { 1 } { 2 } h \eta _ { \mu \nu }$ we get the simple expression

$$ \square \bar { h } _ { \mu \nu } = - 16 \pi G T _ { \mu \nu } $$

which is entirely equivalent to the ones given by @Danu and @gented, but if we take a simple stationary matter configuration such as a point mass, $M$, centred at the origin:

$$ T_{00} = M \delta^{(3)}(\mathbf{x}) \\ T_{ij} = 0 \ \forall \ i,j=1,2,3 $$

we can easily solve the Einstein Equations since they reduce to the simple wave equations:

$$ \nabla ^ { 2 } \bar { h } _ { 00 } = - 16 \pi G M \delta^{(3)}(\mathbf{x}) \quad \text { and } \quad \nabla ^ { 2 } \bar { h } _ { 0 i } = \nabla ^ { 2 } \bar { h } _ { i j } = 0 $$

The solution to the metric is thus (after plugging in the suitable definitions of $g_{\mu\nu}$, $h_{\mu\nu}$ and $\bar{h}_{\mu\nu}$ )

$$ d s ^ { 2 } = - ( 1 + 2 \phi ) d t ^ { 2 } + ( 1 - 2 \phi ) d \mathbf { x } \cdot d \mathbf { x } $$

with $\phi = \frac{-GM}{r}$ as we all know and love.


Reference:

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You are slightly mixing two different things. One thing is the equation of motion for a particle and the other is the equation of motion for the metric. The short answer to your question is that gravity affects the metric and then the metric affects the motion of the particles. Hence, you need to solve two sets of equations, the former first, the latter then.

Einstein's equations relate the metric to the presence of energy and matter in some point in the universe as $$ R_{\mu\nu}-\frac{1}{2}Rg_{\mu\nu} = \frac{8\pi G}{c^4}\,T_{\mu\nu}\tag{1} $$ where the right hand side contains anything that can generate gravitational fields. Notice, en passant, that additional contributions may be present on the left hand side as $g_{\mu\nu}\Lambda$, but this leads out of topic. However, the solution to $(1)$ is a metric $g_{\mu\nu}(x,t)$ in any point in space and time. Once you have such a metric you plug it in to derive the Levi-Civita connections coefficients $\nabla_j e_k = \Gamma^i_{\phantom{i}jk}e_i$ as $$ \Gamma^i_{\phantom{i}jk}=\frac{1}{2}g^{ir}\Big(\partial_k g_{rj} + \partial_j g_{rk}-\partial_r g_{jk}\Big).\tag{2} $$ Once you have derived the Levi-Civita connections as per $(2)$, you use them into the equation of motion for a single particle which moves along the geodesics of a metric $g$ : $$ \ddot{x}^{\mu}+\Gamma^{\mu}_{\phantom{\mu}\nu\lambda}\dot{x}^{\nu}\dot{x}^{\lambda}=0 $$ the derivative being taken with respect to the path lenght $x^{\mu}(s)$.

As an example, if you solve $(1)$ using the stress-energy tensor for a point particle far away from the observer, plug the resulting metric in $(2)$ and then solve the equations of motion, you will get back exactly the standard Newton's law for a particle in a spherical potential.

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  1. On one hand, the geodesic equation yields the gravitational acceleration as $$ -\partial_i \phi~=~ g^i~=~-c^2\Gamma^i_{00}~=~\frac{c^2}{2}\partial_i g_{00}, \qquad i~\in~\{1,\ldots,d\},\tag{1}$$ to leading order in reciprocal speed of light $c^{-1}$, so that the gravitational potential $\phi$ satisfies $$ -g_{00}~=~1 +\frac{2\phi}{c^2}, \tag{2}$$ cf. e.g. Danu's answer.

  2. On the other hand, the weak field approximation $$-\frac{1}{2}\Box \bar{h}^{\mu\nu}~=~\kappa T^{\mu\nu}, \qquad \mu,\nu~\in~\{0,1,\ldots,d\}, \tag{3} $$ to the EFE becomes simple if written in terms of the trace-reversed metric $$\begin{align}g_{\mu\nu}~&=~\eta_{\mu\nu}+h_{\mu\nu}, \cr \bar{h}_{\mu\nu}~:=~h_{\mu\nu}-\frac{1}{2}\eta_{\mu\nu}h \qquad&\Leftrightarrow\qquad h_{\mu\nu}~=~\bar{h}_{\mu\nu}-\frac{1}{d-2}\eta_{\mu\nu}\bar{h}, \end{align} \tag{4}$$ in the Lorenz gauge $$\partial_{\mu} \bar{h}^{\mu\nu} ~=~0, \qquad \nu~\in~\{0,1,\ldots,d\}. \tag{5}$$ This can be recast as gravitoelectromagnetism (GEM), cf. e.g. this Phys.SE post. It turns out that the gravitoelectric potential $\bar{\phi}$ is related to the trace-reversed metric $$ \bar{h}_{00}~=~-\frac{4\bar{\phi}}{c^2} \tag{7}$$ and satisfies Poisson's equation $$ \nabla^2\bar{\phi}~\approx~\Box \bar{\phi}~=~4\pi G\rho \tag{8}$$ in analogy with Gauss' law for Newtonian gravity.

    The underlying reasoning of above section 2 is closely related to alfred's answer.

  3. Finally let us compare section 1 and 2. One may show that the gravitational potential $$\phi~\stackrel{(2)+(4)+(7)}{=}~2\frac{d-3}{d-2}\bar{\phi}\tag{9}$$ is proportional to the gravitoelectric potential $\bar{\phi}$. In $d=4$ they are the same. Interestingly, the gravitational potential (9) vanishes in $d=3$, which is related to the fact that GR is then a topological field theory, cf. e.g. this Phys.SE post.

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