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Is the gravitational constant $G$ a fundamental universal constant like Planck constant $h$ and the speed of light $c$?

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Real "fundamental" constants should be dimensionless, i.e. numbers that don't depend on units. The existence of $c$ is simply due to the Lorentzian nature of spacetime; it's value is only a matter of choice of unit. The existence of $\hbar$ is simply due to the path integral or canonical commutation relations, whose value is again a matter of choice of unit. Similar for Boltzmann constant etc.

On the other hand, the fine structure constant $\alpha\simeq 1/137$ is dimensionless, so this quantity actually means something other than choice of unit. But the number of the quantity is still not that "fundamental" (we will discuss whether the quantity itself is fundamental in the next paragraph) because the number can change by running renormalization flow - i.e. it changes if you define it on different energy scales. So it's the quantity, rather than the number, that has some actual physical meaning.

In the Standard Model of particle physics there are a bunch of such dimensionless quantities. Are these quantities "fundamental"? People tend to believe NO, because Kenneth Wilson let us realize that quantum field theories like the Standard Model are just low energy effective theories that has some high energy cutoff (just like nuclear physics is effective theory of Standard Model); dimensionless quantities in an effective theory should be depend on those in the higher level theory (just like the dimensionless Reynolds number that tell about the behavior of a fluid depends on the molecular constituent of the fluid). String theorists etc are trying to find a theory that has a least number of dimensionless quantities. Some people think an ultimate theory of everything, if exists, should best has no such quantities at all but only numbers that has math significance (like $1, 2, \pi$, or some number with certain analytical, algebraic or topological significance).

In terms of the gravitational constant itself, people generally believe Einstein's General Relativity is an effective theory whose cutoff is about (or lower than) the Planck scale ($\sim 10^{19} GeV$, our temporary experimental reach is $\sim 10^4 GeV$ in the LHC), above which it needs to be replaced by a theory of quantum gravity. But the quantity $G$ might still be there (just like it was from Newton, but still there after Einstein), we are not sure.

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It is probably constant - at least we have no evidence of any change.

"Is it fundamental?" is the big question of theoretical physics. Nobody has yet managed to derive it in terms of more fundamental constant - but a lot of people have tried.

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Yes. I agree with that. Just like Dirac. Pss.. You forgot the formatting in case of your speed-typing eh..? :-) – Waffle's Crazy Peanut Nov 9 '12 at 15:50
@CrazyBuddy - early morning pre-coffee typing! – Martin Beckett Nov 9 '12 at 16:50
Martin, can you give me some sources on those who have tried to derive G in terms of other more fundamental universal constants? – Farhâd Nov 9 '12 at 18:53

There is an alternative to General Relativity known as Brans-Dicke theory that treats the constant $G$ as having a value derivable from a scalar field $\phi$ with its own dynamics. The coupling of $\phi$ to other matter is defined by a variable $\omega$ in the theory, that was assumed to be of order unity. IN the limit where $\omega \rightarrow\infty$, Brans-Dicke theory becomes General Relativity. Current experiments and observations tell us that if Brans-Dicke theory describes the universe, $\omega > 40,000$. Other theories with a varying $G$ would face similar constraints.

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Thanks Jerry. Very useful. – Farhâd Nov 9 '12 at 18:58

Velocity of light $c$, Elementary charge $e$, Mass of the electron $m_e$, Mass of the proton $m_p$, Avogadro constant, $N$, Planck's constant $h$, Universal gravitational constant $G$ and the Boltzmann's constant $k$ are all considered as the fundamental constants in Astrophysics and many other fields.

If any of these values would've to change, there would be a great contradiction differentiating our measured values with that of observed & predicted ones.

  • But, there are cases where $G$ is currently accepted as a variable with some standard deviation 0.003 which is too small. Hence, we use $6.67\times10^{-11}Nmkg^{-2}$ for doing most of our homeworks. The thing is, It's still fundamental...!

So far, investigations have found no evidence of variation of fundamental "constants." So to the best of our current ability to observe, the fundamental constants really are constant.

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I know it's a constant, but I'm asking if it is a "fundamental" universal constant. – Farhâd Nov 9 '12 at 18:50
@Farhâd: Hello Farhad, That's what we all are repeating around. They are fundamental..! – Waffle's Crazy Peanut Nov 10 '12 at 3:04
Why? Just repeating "fundamental" in bold font doesn't make it so. – Farhâd Nov 12 '12 at 13:29

For all intents and purposes, it is a fundamental constant. No one has been able to prove that it isn't fundamental, and within our error in measurement, it's definitely a constant. Like @Crazy Buddy says, $c$ (speed of light), $h$ (Planck's constant), $k_{B}$ (Boltzmann's constant) are all considered to be fundamental constants of the universe. You could have a look at this wiki page.

I think it's important also to realize that the values that they have are only valid within a particular unit convention for measurements. For example, $G = 6.67 \times 10^{-11} m^{3} kg^{-1} s^{-2}$ but this value will obviously change if you measure it in say centimeter-gram-second (cgs units). You could also set $G = 1$ (which they do in Planck units), except the rest of your units will have to change accordingly to keep the dimensions correct.

I hope the last part wasn't confusing.

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