Vanadium 50 said:
Large agnetic fields don't help. In fact, they make things harder. The problem is that the only source of the weak force is the nucleus, and its very far away from where the electron spends most of its time.
So if you have lines from highly ionized atoms that can't be observed on earth. That would help, right? The reason I'm wondering about quasar emission lines is that you see a lot of atoms with lots of electrons stripped off.
Having a large Zeeman shift of both parent and daughter levels doesn't make your signal larger. (Actually, it makes it worse for technical reasons)
I'm been wondering about signal. The thing about quasar forbidden lines is that they are produced by a steady state cascade of electrons. You can have an extremely strong signal from a line with a very weak transition if it turns out that you have a lot of electrons getting tossed in the source level of the line. Also forbidden lines are very sensitive indicators of environment because even tiny changes in transition probability can result in large spectra changes. It's often the case, that you can't see a given transition, but the transition rate changes the electron distribution so that the lines that you can see have very large changes.
Also with Zeeman shifts. If you have a sufficiently high magnetic field then you start getting higher order quantum effects that shift the location of the line. Something that would be interesting to see if any of those higher order effects are influenced by the neutral current. The reason I'm interesting in this is that when you have 10^16 gauss, you end up with all sorts of weird nuclear processes like neutrinos and electrons coming out through bremsstralung. With huge magnetic fields, I'd be interested in thinking of parity non-conserving processes that are something other than the Z-electron interaction.
Your point that none of the experiments that we do in the laboratory will give us a signal in space is well taken, but there is are so many physics processes that I find it very difficult to believe that there wouldn't be *any* sign of parity violation.
The universe at z = 0.1 is not very different than it is today.
I'm thinking about z=6 or z=3000.
Going further back and your putative source gets even weaker, and gets buried even further in the diffuse x-ray background - i.e. the same AGN's that you are counting on for your signal are generating an enormous background.
Not sure. It's an enormous background, but the 511 kev line is at specific frequency. Also there is the issue of resolution. The location of the annihilation may be shifted from the background.
Also, what if the signal comes from behind the AGN background? If we have an anti-matter galaxy, then it's reasonable to assume that it didn't pop into existence suddenly, but that there were anti-matter proto-galaxies, at which point we should see something like the Lyman-alpha forest, only with gamma rays.
There's also the issues of limits. If there was one galaxy or even one planet that space aliens changed into anti-matter, then it would be tough to spot. However, if we assume that the universe has anti-matter/matter zones that are randomly distributed then things are different. If the size of the zone was 50 kpcs (i.e. just larger than one galaxy), then we ought to see a ton of transitions going back to the CMB. If the size of the zone was half the observable universe then maybe we wouldn't see the glow.
Something that would be interesting to calculate are the limits of the number of anti-matter zones.
Many experiments are "nice". This one is "nice". I wish we had the resources to do all the nice experiments out there. Often we're faced with the question of whether you use this particular facility to measure X, Y or Z.
That's when it's nice to have a scientist that good at politics and writing proposals. A lot of science involves selling the idea that spending money to do X is more important than Y. It also helps to own the telescope. In every astronomy project that I've seen, the group that pays for the telescope gets a fraction of time to do whatever they want with it, and sometimes that group got their money from the estate of a rich millionaire that wanted to talk to God (which is what happened with UTexas).
There is some similarity between the world of Hollywood and the world of big ticket science. Often you have a director or star that has this pet project that he wants to work on, so he gets a reputation making movies and finally gets the money and pull to work on the project he *really* is interested in. I've seen the same with big-ticket science. Figuring out what experiment gets done is a lot like figuring out what movie gets made.
On the other hand, I'm more of the "indie film" kind of person. The thing about particle physics is that it's a lot like "Hollywood, big blockbusters." Tons of money, tons of politics, big giant teams. Astrophysics theory is relatively cheap, so you can go out with your digital camera, a few friends and make a movie without that bureaucracy.
