Quote:
Originally Posted by Solanum
Well, I know that if I don't get the results I expect the first thing I check is my instrumentation! However, one hopes that on things of this scale they are pretty sure they haven't stuffed up. I think it just rules out a pretty small subset of theories, as it limits the size of gravitational waves.
It would indeed be interesting if the don't find any. It's about time something in the standard model severely didn't work, give the theorists a bit more of a hard time!
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Yeah I would assume they've checked their results and instrumentation, but you never know there's always the chance that even the checks haven't been successful.
It's an interesting subject to follow
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As I understand it, we should find gravitational waves eventually - we have evidence that they exist from energy loss of binary star, pulsar and black holes systems.
The really interesting thing I'm waiting for is the determination of the speed of transmission of gravity waves - and we can't do that until we can detect them directly. Now, I'm follower of scientific method and happy to be proven wrong... I'll follow the best evidence we have!
... but it strikes me we are currently working on trying to prove the unification of the forces. That is, that gravitation is of the same ilk as the other forces and therefore can only be transmitted at the speed of light.
Indulge me for a moment in a little thought experiment (or two). If gravitation (and gravitational waves) are transmitted at the speed of light, then how does a black hole continue to influence the space around it? Shouldn't the gravity / gravity waves / gravitons obey the event horizon just like light and everything else does? And if it did, shouldn't a black hole gravitationally "disconnect" from the rest of the universe when it forms?
Suppose, gravitation was transmitted faster than the speed of light, perhaps even instantaneously. Gravity / Gravity waves can then escape the event horizon of a black hole, which we observe (gravity is observed, that is, gravity waves we haven't detect yet).
Relax... don't jump to conclusions yet!
Here comes thought experiment no 2... Suppose gravitation is transmitted faster than the speed of light - lets say instantaneously for simplicity and because we have no evidence to suggest an intermediate speed. What effect would the rest of the universe outside the observable universe have on the universe that we can see? Wouldn't the effect be similar to what we observe as "dark energy"?
All fanciful and ridiculous stuff, perhaps, but until we can detect and measure the characteristics of gravitational waves, we won't know. I've pondered these scenarios for a while now, and my hypothesis cannot be reality if gravity operates at the speed of light.
How can gravity exceed the speed of light? It can't be the same type of force as the EM and strong and weak nuclear forces. It would have to be a spacial effect on particles rather than a particle effect or characteristic. We know nothing can exceed the speed of light relative to space, but the expansion of space itself can exceed the speed of light. So a spacial effect could conceivably also act at speeds greater than the speed of light.
I have no evidence what so ever for the above hypothesis
, but if some one can explain to me how gravity works across an event horizon, I'd be most grateful.
Al.
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