Not really. Gravity doesn't much care about how particles interact with other forces.keepitmoving said:does the fact that neutrinos are only weakly interactive change that?
Everything interacts with gravity in pretty much the same way. Neutrinos are weakly-interacting because they don't have any electric or strong force charge. They only interact through gravity and the weak nuclear force, both of which are exceedingly weak compared to the electromagnetic and strong forces.keepitmoving said:In other words, since neutrinos are weakly interactive they didn't know to slow down in the presence of relatively high gravity.
No, exactly the opposite. It means they interact rarely.keepitmoving said:does weakly interacting also mean that they interact infrequently?
Chalnoth said:No, exactly the opposite. It means they interact rarely.
Ack, I read that as "frequently". Sorry!phinds said:Chalnoth, I doubt if you actually meant to say that rarely is the opposite of infrequently.
No, it hasn't been duplicated yet. They're working on it.sirchick said:It was duplicated i believe in Japan..
sirchick said:It was duplicated i believe in Japan..
They would rather blame it on limited technology or something.
Pengwuino said:Do you have any real reasons to back up such a garbage statement?
sirchick said:From reading interviews a lot of scientists are pretty happy to suggestion there is a error on our part rather than them being faster than light. They favour that notion over the possibility of neutrinos being at all faster.
I believe it will take a lot of time to actually convince some scientists there is no mistake on our part if the results did retain the same results.
Yeah, well, I'm betting that we'll still be seeing people running on about FTL neutrinos ten or twenty years from now, long after the result has been disproven and the mistake found.sirchick said:But often favouring an idea can blur your vision from what is actually happening, to the point you dismiss what the facts are telling you.
I believe this will be one case where it will take some time for them to accept what the facts are telling them (if they turn out to be faster than light). It will be slow to be accepted.
Haha, well, it's best not to get attached to any specific result. To me, the really exciting stuff for high energy physics is likely to come when LHC turns back on in a year or two. Then we're likely to get a definitive confirmation or disconfirmation of the tentative detection of the Higgs announced recently, as well as proving entirely new regimes of energy that are likely to demonstrate completely new physics.sirchick said:I hope its not disproven ! Thats not as exciting to me ! ^_^
According to the theory of relativity, the speed of light is the fastest speed at which anything can travel. However, the recent discovery of faster than light neutrinos has sparked a debate among scientists about the possibility of faster-than-light travel.
The discovery of faster than light neutrinos was made by the OPERA (Oscillation Project with Emulsion-tRacking Apparatus) experiment at CERN in 2011. They observed that neutrinos sent from CERN to the Gran Sasso National Laboratory in Italy arrived 60 nanoseconds earlier than expected, indicating that they traveled faster than the speed of light.
Neutrinos are subatomic particles that have a very small mass and no electric charge. They interact very weakly with matter, meaning that they can pass through most materials without any interaction. This makes them very difficult to detect and study.
If the discovery of faster than light neutrinos is confirmed, it could challenge our understanding of the laws of physics and the theory of relativity. It could also have implications for space travel and communication, as faster-than-light travel would allow us to reach distant galaxies in a shorter amount of time.
There is still ongoing research and debate within the scientific community about the discovery of faster than light neutrinos. Some experiments have replicated the results, while others have not. More research and evidence is needed to confirm the existence of faster than light neutrinos and their implications for our understanding of physics.