Is it suspicious that gravitational waves propagate at the speed of light?

Question

Thinking about gravitational waves and the fact that they propagate at the speed of light, I was wondering if it isn't suspicious - the speed of light I mean. Does it perhaps point to something fundamental about the spacetime? Is there maybe some connection between EMR and spacetime itself? Or am I seeing things in the tea leaves?

Answer 1

It is very suspicious! It points to the fact that the speed of light isn't just some random speed that light happens to travel at, but is a fundamental property of the universe.

In fact, any massless particle will move at the speed of light. This is a consequence of relativity. Energy, mass and momentum($p$) are related by

$$E^2 = m^2c^4 +p^2c^2$$

for a particle moving at velocity $v$ less than $c$, $$p = mv\sqrt{\left(\frac{1}{1-(v/c)^2}\right)}$$

if a massless particle ($m=0$) is moving at velocity less than $c$, then it would have zero momentum and zero energy. Such a particle could never be detected (since to be detected a particle has to transfer some of its energy and momentum to the detector). Is it possible for a fundamentally undetectable object to exist? That is a matter for philosophers. For the sake of developing models of reality, such particles don't exist.

Answer 2

The perturbation to the metric of spacetime (known as the strain), caused (for example) by an oscillating mass quadrupole, obeys a wave equation of the form $$ \nabla^2 h^{\mu \nu} = \frac{1}{c^2} \frac{\partial^2 h^{\mu \nu}}{\partial t^2}\, , $$ where $h^{\mu \nu}$ is a 4x4 tensor.

The solutions to this equation are plane waves travelling with a speed $c$, i.e., the speed of light.

Why is this so? Well, I suppose it is because General Relativity is a relativistically covariant theory that works for all frames of reference. This inevitably involves the speed of light as the fastest speed that information can travel. The speed of light, along with $G$, is present in the fundamental Einstein Field Equations in much the same way that the speed of light is present in Maxwell's equations for electromagnetism.

Hence GR predicts that these disturbances should travel at the speed of light and the limited measurements so far indicate that is the case.

Answer 3

This is actually a very good question! I think you find it strange that gravity (or gravitational waves) travels at the same speed as photons, which travel in spacetime. How come that a spacetime disturbance "knows" to travel at the same speed as the photons inside it? If a photon travels inside a gravitational wave, why will it stay in the wave? Which of the two will arrive at the finish first, if they started from the same place (though the place for the wave is a bit hard to formulate, as the GW is a distortion of spacetime itself, while the photon has a position in it) if they are traveling side by side? The photon or the wave?
Both will arrive at the finish first (that is at the same time). They travel in time too. That is, their traveling velocity in time is zero. You can compare this with an infinite traveling speed in classical, absolute spacetime (the one that Newton used). There is simply no higher speed than that. If the gravitational waves were traveling at a higher speed they would get younger which means that they would take the shape they had a moment before. But that would be exactly the shape they had upon leaving, which again means that they wouldn't be able to go forward at all.
So the main point is that the waves simply can't travel at a higher speed than an infinite speed when considered as traveling in absolute spacetime (Newton thought indeed that the gravitational interaction was instantaneous). This translates in a lightspeed in relative spacetime.

In a quantum theory of gravity, gravitons are thought to be traveling through spacetime after a source of matter-energy has produced them. Just as photons are produced by an electric charge. The gravitons travel through flat spacetime just as the photons. They are thought to be massless, and as such they can't travel at a higher speed than the lightspeed. But how can they travel through flat spacetime when the wave is a non-flat piece of spacetime? It is exactly this that makes the finding of a quantum theory of gravity hard. For example, spacetime around a massive object is curved. How can this field be seen as (virtual) gravitons traveling in flat spacetime? For small fields (small masses), you can approximate the spacetime as being flat. But if the field is strong every graviton travels in a spacetime that the other gravitons have already disturbed. This is a bit similar to how gluons in the strong interaction behave. The action of each gluon is affected by the other gluons They emit gluons themselves, like gravitons emit gravitons. The difference is though that gluons are supposed to travel always in a flat spacetime, while gravitons travel in a spacetime that is curved already (by themselves).

Answer 4

Here is a simple aspect that has not been stressed enough (in my opinion) in the answers given so far.

GR states (I’m not sure if as a result or axiom) that there exists a finite maximum speed. This maximum speed is not the speed of light and not the speed of gravitational waves, but all massless particles and gravitational waves happen to (as a consequence of the theory) propagate with that same maximum speed.

If you think it this way there is nothing suspicious about the fact that gravitational waves and light propagate with the same speed. There is nothing suspicious about the fact that the driver of a car happens to travel at the same speed as the passengers.

Answer 5

This is actually pretty complicated to answer, and you should beware of oversimplified answers. And BTW you'd probably be better off asking this on physics.SE.

The state of the art in physics at this point is that we have two totally successful theories that contradict each other. These are quantum mechanics and general relativity.

Quantum mechanics says the way forces are created is that material particles (fermions) exchange bosons. If the boson is massless, then in the classical limit you get a $1/r^2$ force. Massless particles travel at $c$. Therefore if we observe a force that, like gravity, falls off with distance as $1/r^2$, we suspect that it arises from a massless boson. Massless bosons travel at $c$, ergo gravitational signals should travel at $c$. This all sounds great, except that quantum mechanics doesn't work as a theory of gravity, which throws everything into doubt.

General relativity (GR) works great as a classical theory of gravity, and it's been spectacularly confirmed in the strong-gravity regime by recent observations of gravitational waves and the event horizons of black holes. But GR does not really predict that gravitational waves travel at $c$. Actually GR tells us that speed is not really a very meaningful concept. For example, it refuses to answer the question of whether a distant galaxy is actually moving away from us at some speed, or whether both our galaxy and that one are at rest, while the space in between expands. All GR really says is that in the limit of low amplitudes, on a background of flat spacetime, it's meaningful to talk about the speed of gravitational waves, and in that same limit they travel at $c$.

So it's not really true and not really predicted by the known laws of physics that gravitational waves travel at $c$. However, it's intuitively obvious to physicists, in the view from 40,000 feet, that it must be so in cases of practical interest, based on a general feel for how physics works.