Is anti-matter as exciting as (some) matter, at zero temperature?
Or can they not be mixed?
Answers:
Anti-Matter has the same theoretical properties as regular matter, at the current stage (epoch) of the universe, so given the proper conditions atoms made of anti-matter, will form a Bose-Einstein condensate, which is the exciting property I think you are talking about, at very low temperatures.
As for your second question, anti-matter can in fact annialate itself with regular matter, even at absolute zero (were it possible to achieve this temp). It is a common mistake to assume zero motion at zero temperature, there can be motion, it just can't be random. And since the attraction of an anti-atom to an atom is definitley not random, it is still possible at zero temperature.
As a side note, and really just a nit-pick, zero degrees is an impossible temperature to achieve, not just practically, but theoretically too, by the uncertainty principle. So I assume you mean near zero temperature.
for real excitement, try mega-matter!
Anti matter behaves in a similar way to normal matter. It is just that the particles cannot co-exist. They annihilate one another. Anti matter exists in nature (for instance, it can be produced by Beryllium). It is not some science fiction exotic thing. Matter ant-matter collisions are occurring all the time but usually too infinitesimal for us to detect.
No clue!
Your pretty much asking if Anti-matter and matter COULD be mixed without annihilating eachother IF they were in absolute zero?
Since I really don't know that much -- not sure if anyone does -- about the annihilation process, I do not know. Technically, however, it would make sense that in absolute zero there is no way for them to merge.. then again what could you do with it? Nothin =P
all matter behave exactly the same.
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Answers:
Anti-Matter has the same theoretical properties as regular matter, at the current stage (epoch) of the universe, so given the proper conditions atoms made of anti-matter, will form a Bose-Einstein condensate, which is the exciting property I think you are talking about, at very low temperatures.
As for your second question, anti-matter can in fact annialate itself with regular matter, even at absolute zero (were it possible to achieve this temp). It is a common mistake to assume zero motion at zero temperature, there can be motion, it just can't be random. And since the attraction of an anti-atom to an atom is definitley not random, it is still possible at zero temperature.
As a side note, and really just a nit-pick, zero degrees is an impossible temperature to achieve, not just practically, but theoretically too, by the uncertainty principle. So I assume you mean near zero temperature.
for real excitement, try mega-matter!
Anti matter behaves in a similar way to normal matter. It is just that the particles cannot co-exist. They annihilate one another. Anti matter exists in nature (for instance, it can be produced by Beryllium). It is not some science fiction exotic thing. Matter ant-matter collisions are occurring all the time but usually too infinitesimal for us to detect.
No clue!
Your pretty much asking if Anti-matter and matter COULD be mixed without annihilating eachother IF they were in absolute zero?
Since I really don't know that much -- not sure if anyone does -- about the annihilation process, I do not know. Technically, however, it would make sense that in absolute zero there is no way for them to merge.. then again what could you do with it? Nothin =P
all matter behave exactly the same.
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