Quantcast
  • Register
PhysicsOverflow is a next-generation academic platform for physicists and astronomers, including a community peer review system and a postgraduate-level discussion forum analogous to MathOverflow.

Welcome to PhysicsOverflow! PhysicsOverflow is an open platform for community peer review and graduate-level Physics discussion.

Please help promote PhysicsOverflow ads elsewhere if you like it.

News

PO is now at the Physics Department of Bielefeld University!

New printer friendly PO pages!

Migration to Bielefeld University was successful!

Please vote for this year's PhysicsOverflow ads!

Please do help out in categorising submissions. Submit a paper to PhysicsOverflow!

... see more

Tools for paper authors

Submit paper
Claim Paper Authorship

Tools for SE users

Search User
Reclaim SE Account
Request Account Merger
Nativise imported posts
Claim post (deleted users)
Import SE post

Users whose questions have been imported from Physics Stack Exchange, Theoretical Physics Stack Exchange, or any other Stack Exchange site are kindly requested to reclaim their account and not to register as a new user.

Public \(\beta\) tools

Report a bug with a feature
Request a new functionality
404 page design
Send feedback

Attributions

(propose a free ad)

Site Statistics

206 submissions , 164 unreviewed
5,103 questions , 2,249 unanswered
5,355 answers , 22,794 comments
1,470 users with positive rep
820 active unimported users
More ...

  How to obtain the field equations in Brans-Dicke theory from the action?

+ 4 like - 0 dislike
3486 views

The action for the Brans-Dicke-Jordan theory of gravity is $$ \\S =\int d^4x\sqrt{-g} \; \left(\frac{\phi R - \omega\frac{\partial_a\phi\partial^a\phi}{\phi}}{16\pi} + \mathcal{L}_\mathrm{M}\right). $$ And the field equations of the gravitation field are $$ G_{ab} = \frac{8\pi}{\phi}T_{ab}+\frac{\omega}{\phi^2} (\partial_a\phi\partial_b\phi-\frac{1}{2}g_{ab}\partial_c\phi\partial^c\phi) +\frac{1}{\phi}(\nabla_a\nabla_b\phi-g_{ab}\Box\phi). $$ I tried to vary this action w.r.t $g_{ab}$ but failed. How can I obtain these from the action? Where can I get the detailed derivation? Thx!


This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user DHA

asked Dec 10, 2013 in Theoretical Physics by DHA (20 points) [ revision history ]
edited Dec 31, 2014 by Dilaton
What have you tried so far? Are you familiar with how to vary the Einstein Hilbert action (see eg: en.wikipedia.org/wiki/…)? If you can handle the Einstein Hilbert action, this is a relatively simply extension. To vary the Brans Dicke action wrt $g^{ab}$ you only need to know how to vary $\sqrt{-g}$, $R$, and $g^{ab}$, all of which appear in varying Einstein Hilbert. (Technical aside: it's usually easier to vary wrt $g^{ab}$ than $g_{ab}$).

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user Andrew
Also if you look at the eoms, $G_{ab}$ and $T_{ab}$ make sense, they appear after varying Einstein Hilbert. The term proportional to $\omega$ is the stress energy for a scalar field, so that makes sense. The tricky term is the last one. There are some integrations by parts you have to do in varying the Einstein Hilbert term. Since $\phi$ multiples $R$, you will pick up some extra derivatives on $\phi$ when you vary $\sqrt{-g} \phi R$ that were not present after you vary $\sqrt{-g} R$. Again, if you go through varying the Einstein Hilbert action carefully, you can see how this term arises.

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user Andrew
I can derive the Einstein equations from the Einstein Hilbert action, but when I vary $\sqrt{-g}\phi R$ I cannot get the extra derivatives on $\phi$. Where can I find some details about this derivation? Thx.

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user DHA
Hm, I don't know a source that does it in detail. But here's basically how it works. On wikipedia you can see that $\delta R^\mu_{\ \nu\rho\sigma}\sim\nabla \delta \Gamma$. In $\sqrt{-g}R$, this leads to a term $\sqrt{-g} \nabla(\delta \Gamma)$, which is a total derivative. However in Brans Dicke you have $\sqrt{-g} \phi \nabla (\delta \Gamma)$, which is not a total derivative. You need to re express $\delta \Gamma$ in terms of $\delta g$, then integrate the $\nabla$ onto $\phi$. There is a handy trick: in the locally inertial frame $\nabla \delta \Gamma = \partial \delta \Gamma$.

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user Andrew
Maybe this paper will interest you, while treating a more general case. The general Euler-Lagrange equations are given by equations $2,3$. Standard Brans-Dicke corresponds to $f= -\omega \frac{\partial_\mu \phi \partial^\mu \phi}{\phi}$, take also $J=\Lambda=0$), see equations $12,13$. Be careful that you have coupled equations, for instance $\square\phi$ depends on $T$ and $\omega$, so you may have different (but equivalent) representations for the Euler-Lagrange equations.

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user Trimok
See also wiki1 and wiki2

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user Trimok
Duplicate: physics.stackexchange.com/questions/93157/…

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user Prahar

3 Answers

+ 2 like - 0 dislike

I have been in your situation. I agree with Andrew and I've found this helpful http://arxiv.org/abs/1002.0617v4. Go directly to appendix B, There you will find the answer of an identical problem and you shall use appendix A, as well.

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user maha
answered Jan 31, 2014 by maha (30 points) [ no revision ]
Hi maha, we usually expect answers to stand on their own. Can you include a brief summary of the solution you link to or quote some of the useful content?

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user Brandon Enright
@Brandon Well,I'm actually a beginner in the field and as you can see I avoided to use any symbol because I can't use the TeX language yet.Also I have no reputation yet to try guiding DHA via a comment.So I had to use what I'm allowed to which was answering! However I shall edit my answer as soon as possible.Thanks Brandon.

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user maha
+ 1 like - 0 dislike

The action which describes Brans-Dicke theory is given by,

$$S=\frac{1}{16\pi G}\int d^4x \, \sqrt{|g|} \left( -\Phi R + \frac{\omega}{\Phi}\partial_\mu \Phi \partial^\mu \Phi \right)$$

which features a scalar field $\Phi$ coupling to gravity through the Ricci scalar, and with its own kinetic term. To obtain the equations of motion, we vary our action with respect to the scalar and metric, like so,

$$\delta S = \frac{1}{16\pi G} \int d^4x \, \delta \Phi \left( -R - \frac{2\omega}{\Phi} \square \Phi + \frac{\omega}{\Phi^2} \partial_\mu \Phi \partial^\mu\Phi\right)$$ $$-\delta g^{\mu\nu} \left(\Phi G_{\mu\nu}-\frac{\omega}{\Phi} \partial_\mu \Phi \partial_\nu \Phi + \frac{1}{2}g_{\mu\nu}\frac{\omega}{\Phi}\partial_\lambda \Phi \partial^\lambda \Phi\right) + \Phi (\nabla_\mu\nabla_\nu \delta g^{\mu\nu}-\square g_{\mu\nu}\delta g^{\mu\nu})$$ where we have already performed an integration by parts. From the variation, we may deduce, $$\Phi G_{\mu\nu} - \nabla_\mu \nabla_\nu \Phi + g_{\mu\nu} \square \Phi - \frac{\omega}{\Phi} \left( \partial_\mu \Phi \partial_\nu \Phi - \frac{1}{2}g_{\mu\nu} (\nabla\Phi)^2\right) = 8\pi T_{\mu\nu}$$

for some background matter with stress-energy tensor $T_{\mu\nu}$. There is an additional equation of motion due to the scalar field, namely,

$$\Phi R + 2\omega \square \Phi - \frac{\omega}{\Phi} (\nabla\Phi)^2 = 0$$

which is zero providing the scalar field does not couple to the background matter. We can now take a trace with respect to the metric of the first equation, obtaining,

$$-\Phi R+3\square \Phi + \frac{\omega}{\Phi}(\nabla \Phi)^2 = 8\pi T$$

presuming $d=4$, where $T \equiv T^\mu_\mu$. Adding this equation to the previous, we find,

$$(3+2\omega) \square \Phi = 8\pi T.$$

The parameter $\omega$ measures how strongly $\Phi$ couples to matter content. We can rewrite the 'Einstein' field equations as,

$$R_{\mu\nu}-\frac{1}{\Phi}\nabla_\mu \nabla_\nu \Phi + \frac{1}{\Phi}g_{\mu\nu} \square \Phi - \frac{\omega}{\Phi^2}\partial_\mu \Phi \partial_\nu \Phi = \frac{8\pi}{\Phi}T_{\mu\nu} - g_{\mu\nu}\frac{\omega}{\Phi} \Phi \square \Phi$$

by expanding the Einstein tensor and substituting the relation between the Ricci scalar and field. We can now write a relation between the Ricci tensor, field and stress-energy tensor, namely,

$$R_{\mu\nu}-\frac{1}{\Phi}\nabla_\mu \nabla_\nu \Phi - \frac{\omega}{\Phi^2}\partial_\mu \Phi \partial_\nu \Phi = \frac{8\pi}{\Phi} \left( T_{\mu\nu}-\frac{(\omega+1)}{(3+2\omega)}T g_{\mu\nu} \right)$$

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user JamalS
answered Dec 30, 2014 by JamalS (895 points) [ no revision ]
+ 0 like - 0 dislike

In "The Scalar-Tensor Theory of Gravitation", of Yasunori Fujii and Kei-ichi Maeda you can find explicitly the solution, in Appendix C (pag. 195). Personally, I really didn't like this book and even this demonstration it's very difficult to follow.

So I did it in another way. Use the usual theory for the GR part, and isolate this term:

$\int d^4 x \sqrt{-g}\Phi \delta R_{\mu\nu}g^{\mu\nu} $

Then you can use the Palatini Identity: \begin{equation} \delta R_{\mu\nu}=\left( \delta \Gamma^{\alpha}_{\mu\nu} \right)_{;\alpha}-\left( \delta \Gamma^{\alpha}_{\mu\alpha} \right)_{;\nu} \end{equation}

So:

\begin{equation} \begin{split} \delta R_{\mu\nu}g^{\mu\nu} &=g^{\mu\nu}\left[ \left( \delta \Gamma^{\alpha}_{\mu\nu} \right)_{;\alpha}-\left( \delta \Gamma^{\alpha}_{\mu\alpha} \right)_{;\nu} \right]= \dots \\ & \dots =\left(g^{\mu\nu} \delta \Gamma^{\alpha}_{\mu\nu} \right)_{;\alpha}-\left(g^{\mu\nu} \delta \Gamma^{\alpha}_{\mu\alpha} \right)_{;\nu}=\left(g^{\mu\nu} \delta \Gamma^{\beta}_{\mu\nu} -g^{\mu\beta} \delta \Gamma^{\alpha}_{\mu\alpha} \right)_{;\beta} \end{split} \end{equation}

In GR you don't have $\Phi$, so this term simply goes to zero thanks to Gauss's Theorem. Now you need to integrate by parts twice. The second integration by parts comes from the explicit expression of $\delta \Gamma^{\alpha}_{\mu\nu}$. In order to simplify, go into a Locally inertial frame, where:

\begin{equation} \delta \Gamma^{\beta}_{\mu\nu}=\frac{1}{2}g^{\rho\beta}[ \left(\partial_\nu \delta g_{\rho\mu}\right)+\left(\partial_\mu \delta g_{\rho\nu} \right)-\left(\partial_\rho \delta g_{\nu\mu} \right) ] \end{equation}

At the end go to a general frame, so $\partial \rightarrow \nabla$. These are all the difficult steps, there are some simple calculations to be done in the middle.

This post imported from StackExchange Physics at 2014-12-31 12:12 (UTC), posted by SE-user Rexcirus
answered Jul 15, 2014 by Rexcirus (20 points) [ no revision ]

Your answer

Please use answers only to (at least partly) answer questions. To comment, discuss, or ask for clarification, leave a comment instead.
To mask links under text, please type your text, highlight it, and click the "link" button. You can then enter your link URL.
Please consult the FAQ for as to how to format your post.
This is the answer box; if you want to write a comment instead, please use the 'add comment' button.
Live preview (may slow down editor)   Preview
Your name to display (optional):
Privacy: Your email address will only be used for sending these notifications.
Anti-spam verification:
If you are a human please identify the position of the character covered by the symbol $\varnothing$ in the following word:
p$\hbar$ysicsOverf$\varnothing$ow
Then drag the red bullet below over the corresponding character of our banner. When you drop it there, the bullet changes to green (on slow internet connections after a few seconds).
Please complete the anti-spam verification




user contributions licensed under cc by-sa 3.0 with attribution required

Your rights
...