Nano

Thanks for a detailed explanation of the SN type II. The neutrinos are light, but do indeed have high velocity therefore also momentum. I can understand that their kinetic energy would blast the outer layers of, remembering that it is a vast amount of those small bastards coming from the core. The problem, as you also pointed out, is that neutrinos hardly interact with ordinary matter, which the outer layers consist of. In this very second 50 trillion solar neutrinos passes through your body (Wikipedia)

As far as I've understood, the whole supernova process starts with that the core is collapsing when the gravitational force is grater than the electron degeneracy pressure. This collapse happens in a very brief amount of time, and it reach to a sudden halt when the neutron-pressure and the weak force is holding back gravity for collapsing even further. Apparently it is this "halt" which is triggering the outer layers to explode. My question is how do the core and the outer layers interract? Is it particles which is carrying the kinetic energy from the core to the outer layers?

You are right offcourse. I am still in the learning process of relativity. So a person inside a spaceship traveling close to c relative to us, would not "feel" any of the relativitsic effect? A watch carried by the captain would, in his opinion, click just normally? He would not gain any mass, or change his size? If two spaceships leaves from earth traveling at a speed close to c but in in opposite directions relative to the earth, they would still travel extremely close to c relative to each other?

I think that for relativistic effects to take place (time dilation, mass increase and lenght contraction) the spaceship have to travel close to c , relative to the space-time continuum. There is nothing special about earth, so why should the spaceships speed be measured relative to us?

Aha, I misunderstood you in the start of the thred. I agree also that the photon would reach us. It would also offcourse have a speed of c when it did.

Since space-time is getting bigger, shouldn't the EM-field in which the photon is traveling through as a medium also expand proportional to the space-time? Meaning that the photon would have a longer a distance to travel?

Would the lightbeam ever reach us at all, if space which light is traveling through is expanding faster than the light itself?

The formation of bright and dark lines on the screen has nothing to do with the photons energy. (except that the distance between the lines are dependent on the photons frequency) It is interference and probability that creates the pattern. If you sent only one photon through the slits, it could end up everywhere on the screen, but it would most likely end up near the bright lines. "Most likely" is then another way to say "high probability". A photon can be many places at the same time, but it can only be absorbed by one atom at one point in time. Therefore will it not be smeared out over the detector. Don't know if I understood your questions right. My head is a bit slow

Understaning this phenomena can be difficult to grasp, as anything else in quantum mechanics. I am really not a particle physicist, but I can tell you the way I've understood it. When we say that a photon (or electron or other particles) are waves, we have to understand what is actually waving. For example watermolecules waves in crests, sounds waves in contraction, but particles wave in probability. Meaning that a particle is at many places at the same time, but when we look at it, it is a certain probablilty for it to be one place, and a different probability for it to be another place. My key to accept this fact, was to read about Thomas Young double-split experiment. Are you familiar with that?

The photons are "smeared" out all over the place, which means that one photon is at many different places at the same time. The photons in a cubic meter will overlap each other, so there is no real place where the photon "ends". I don't mean to hijack your thread, but I wonder if the probability for a photon to be at a certain place at a certain time is ever = 0? Will it not just gradually get smaller and smaller until it is reaching infinitesimal size?

Thanks mate! I recently got the high def. version of "Into the Universe With Stephen Hawking" (also featured on that site in a low level res.). The animations in the film are just fantastic in HD. It's on a completely different level than other series about the universe. The explanations is quite basic stuff though, but I watched it for the graphics. Anyway, cool site

I don't know, and that was also the reason why I said that someone else have fill me in (check the post) whether it is possible to distinguish it from radiaion emitted from elsewhere than a BH.. aarg. Thanks for filling in

Remember that it is possible in theory to travel great distances in short time. If technology finds a way to exploit worm-holes, we might get much closer to a black hole. The radiation might also find it's way to us through worm holes.

It's funny that the "standard model" is thought to be the most successful description of how all particles and forces interact, but still whenever you ask quantum mechanics about gravity, they're goin' : "Hmm, oh yea, gravity. I'd forgotten about that..uuh, something to do with gravitons" As you understand, I am no professor, and have not the slightest idea what gravity is on a basic level, except an exchange of gravitons. I'm still waiting for someone to explain it though. I think Einsteins GR is the most elegant theory, but that's only me. I guess someone with more knowledge have to fill in the facts and give us the solutions to the mysteries of gravity.

Einsteins GR predicted them, and that theory has been verified a lot of times. "Real proof" of a BH is a bit tricky since they hardly emit radiation. Maybe somebody else can fill me in whether Hawkins theory of escaping particles from the edge of the event horizon could one day be detected and linked to being emmited from a black hole? The way astronomers detect them today is through gravity. When a BH passes our vision of a distant star, it will bend the light from all directions around it, making it look like several similar stars here from earth, when in fact there is only one.