Assumption that Anti-Matter Galaxies Would Emit Detectable Gamma Ray Bursts

In summary: We do see a gamma ray background, but it's 10^-5 lower than what we'd see if the universe were completely made of antimatter.In summary, the tools that we are currently using to find antimatter galaxies look for gamma rays that are emitted due to annihilation events. The hypothesis is that these annihilation events would occur along matter-antimatter boundaries. However, there are some questions about this hypothesis. One possibility is that there are no boundaries, and that these galaxies exist in virtual isolation from matter. Another possibility is that there are boundary regions, but we don't know how to find them. Furthermore, cosmology gives us the amount of stuff in the universe.
  • #1
Cadaei
24
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In the hunt for antimatter galaxies, the tools that we are currently using look for gamma rays that would be emitted due to annihilation events, because everything else about these galaxies is predicted to be the same emission-wise. The hypothesis is that these annihilation events would occur along matter-antimatter boundaries.

However, why would we even assume that these boundaries exist? If there are entire galaxies composed of antimatter, how do we know that there would be these events at all? It could be true that these galaxies exist in virtual isolation from matter due to the vast distances between galaxies.

Furthermore, the very same annihilation events should theoretically occur in a mostly matter galaxies. For example, there are large clouds of antimatter within our own galaxy. Would not the number of annihilation events in a galaxy that were say 90% matter and 10% antimatter be *exactly* the same as in a galaxy that is 90% antimatter and 10% matter? Wouldn't there be no difference in the emitted gamma rays?
 
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  • #2
However, why would we even assume that these boundaries exist? If there are entire galaxies composed of antimatter, how do we know that there would be these events at all? It could be true that these galaxies exist in virtual isolation from matter due to the vast distances between galaxies.

True, but one would expect that at least one matter-antimatter pair would be close enough together to "try" to merge. There are at least a few pairs of matter-matter galaxies that seem to have some overlap

For example, there are large clouds of antimatter within our own galaxy.

I'm most probably wrong here, but I can't seem to remember anything about clouds of antimatter in the Milky Way.
 
  • #3
For an in depth discussion of this issue, see "A Matter-Antimatter Universe?"
http://arxiv.org/abs/astro-ph/9707087. Note that Sheldon Glashow is one of the authors, so the paper has some 'star' power.
 
  • #4
Even without overlap, the space between galaxies is not completely empty. There would be some boundary regions, with matter and antimatter at the same time.
 
  • #5
mfb said:
Even without overlap, the space between galaxies is not completely empty. There would be some boundary regions, with matter and antimatter at the same time.

Maybe there used to be, but those regions are now empty because the matter-antimatter reactions have already taken place.

The other possibility is that there do exist boundary regions which are beyond our cosmic horizon, 40+Gly away.
 
  • #6
mrspeedybob said:
Maybe there used to be, but those regions are now empty because the matter-antimatter reactions have already taken place.

Except that they aren't empty. We can see hydrogen lines.

Also, cosmology gives us the amount of stuff in the universe.

The other possibility is that there do exist boundary regions which are beyond our cosmic horizon, 40+Gly away.

That's possible, but getting the physics to do that is tricky. The problem is that if you have a mix of matter and anti-matter there's not any known way of making them "clump". You also run into "speed of light" problems. The problem is that the important reactions that produce matter/anti-matter differences happened after the universe had inflated and was expanding slowing.

So if one part of the universe was "matter" it's hard to tell the rest of the universe that it should also be "matter".

Right now the assumption is that there is some asymmetry that we don't know about in high energy particle reactions. Even though there are only two reactions that we do know about that aren't symmetric, that at least tells us that it's possible.
 
  • #7
twofish-quant said:
Right now the assumption is that there is some asymmetry that we don't know about in high energy particle reactions. Even though there are only two reactions that we do know about that aren't symmetric, that at least tells us that it's possible.
Which reactions do you mean? CP-violation was observed both in the kaon and B-meson system, with multiple different observables. At D-mesons, there are first hints for CP-violation, too (with 0 excluded at 3.8 standard deviations).

Maybe there used to be, but those regions are now empty because the matter-antimatter reactions have already taken place.
And what prevents matter and antimatter from (relatively...) nearby galaxies to go into this region again? The global structure of the visible matter/antimatter does not contain isolated regions, it is like a large "network" with some large voids in between (nearly without galaxies - neither matter nor antimatter).
 
  • #8
mfb said:
Which reactions do you mean? CP-violation was observed both in the kaon and B-meson system, with multiple different observables. At D-mesons, there are first hints for CP-violation, too (with 0 excluded at 3.8 standard deviations).

OK. Now three :-) :-)

The other thing is that large amounts of anti-matter wouldn't produce "bursts". They'd produce this diffuse gamma ray background. Now we do see a gamma ray background, but it's 10^-5 lower than what we'd see if there were matter/anti-matter interactions in the intergalactic media.
 

What is anti-matter and why is it important in the study of galaxies?

Anti-matter is the opposite of regular matter, with particles that have the same mass but opposite charge. It is important in the study of galaxies because it helps us understand the fundamental laws of physics and the origins of the universe.

What is a gamma ray burst and how is it related to anti-matter galaxies?

A gamma ray burst is a short burst of high-energy electromagnetic radiation. It is related to anti-matter galaxies because it is hypothesized that the collision of anti-matter particles in these galaxies could produce detectable gamma ray bursts.

How do scientists detect gamma ray bursts from anti-matter galaxies?

Scientists use specialized telescopes and detectors, such as the Fermi Gamma-ray Space Telescope, to detect gamma ray bursts. These instruments are able to detect the high-energy radiation emitted during a burst and determine its location in the sky.

What evidence supports the assumption that anti-matter galaxies would emit detectable gamma ray bursts?

There is currently no direct evidence for the existence of anti-matter galaxies or the emission of gamma ray bursts from them. However, theoretical models and simulations suggest that such bursts would be a natural consequence of anti-matter collisions in these galaxies.

What implications would the detection of gamma ray bursts from anti-matter galaxies have on our understanding of the universe?

The detection of gamma ray bursts from anti-matter galaxies would provide valuable insights into the behavior of anti-matter and its role in the universe. It could also help us better understand the origins of the universe and the fundamental laws of physics.

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