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Of course it is.Andreas C said:Some of those are also theoretically impossible, a perfect vacuum isn't.
Of course it is.Andreas C said:Some of those are also theoretically impossible, a perfect vacuum isn't.
sophiecentaur said:Of course it is.
Tons? = Mass = vacuum??Andreas C said:Theoretically impossible? No, there are tons of it everywhere.
sophiecentaur said:Tons? = Mass = vacuum??
sophiecentaur said:But how would you define your perfect vacuum? How big a volume and for how long would you have to have your vacuum exist?
sophiecentaur said:The only way you could actually check that it's there would be to measure the presence of atoms and your atom detector could have missed that final atom in the time (however long) taken for the experiment.
sophiecentaur said:Specify some particular conditions and you can get a sensible answer (albeit very ball park).
Mine too.Andreas C said:It's a 'joke",
MUCH better. That takes us from nonsense to almost sense.Andreas C said:Alright then. How about getting less than 10 atoms per cc? Is that better?
Haha. You would need to talk to a Mathematician about that statement and it's all relative. But you are now talking in the terms that can actually get an answer.Andreas C said:Less than 10 is practically nothing.
sophiecentaur said:Mine too
sophiecentaur said:That takes us from nonsense to almost sense.Except for the 'perfect detector' and the 'very long'. In some fields of study, 'very long' could be 1ns.
sophiecentaur said:Haha. You would need to talk to a Mathematician about that statement and it's all relative
sophiecentaur said:AP minus a small number is much the same as AP minus a really small number
Of course it is. None of this has any practical application.Andreas C said:Do you think this is a game?
jbriggs444 said:Of course it is. None of this has any practical application.
This is the vacuum thread, not the sucking noodle thread. That thread is much more than a game.Andreas C said:Are you telling me that performing an experiment involving sucking noodles with the utmost precision has no practical application? What are you going to say next, that it's useless to think of how many angels can dance on the head of a pin?![]()
jbriggs444 said:This is the vacuum thread, not the sucking noodle thread. That thread is much more than a game.
mfb said:The BASE experiment at CERN made a vacuum so good that they couldn't detect any remaining gas, and set an upper limit of 3 particles per cm3. Even if the density is at the upper limit, based on Poisson statistics, cubic-centimer-sized regions free of atoms occur all the time. Or, put differently, if their trap would be smaller there would be a reasonable chance to have 0 atoms in it.
Well, at least a year, that's how long the antiprotons were in it.Andreas C said:That's amazing! How long was this maintained?
Same approach: Cooling. Start with a very good vacuum, then seal the chamber completely, then cool it. All the remaining atoms freeze out at the walls.Andreas C said:How did they manage to evacuate the chamber so well?
mfb said:nd set an upper limit of 3 particles per cm3. Even if the density is at the upper limit (it is expected to be at least 1-2 orders of magnitude better),
Vanadium 50 said:Ref. [17] would be nice to look at, if it were complete or pointed at a preprint.
See the first link (post 41):Vanadium 50 said:Where do you see this?mfb said:nd set an upper limit of 3 particles per cm3. Even if the density is at the upper limit (it is expected to be at least 1-2 orders of magnitude better),
“Given that we have not observed any antiproton disappearance yet,” says Christian Smorra, a research fellow on the BASE collaboration, “we can say that there are less than three matter particles left per cubic centimetre.”
That is based on 3 months, they have more than a year now.Andreas C said:I'm not sure if it is what you're looking for, but it seems to refer to p. 24 of this: http://cds.cern.ch/record/2120817/files/SPSC-SR-177.pdf
It just mentions that the storage time is more than 1.08 years.
mfb said:That is based on 3 months, they have more than a year now.
Interesting. I'm guessing this is why: "When astronauts return from space walks and remove their helmets, they are welcomed back with a peculiar smell. An odor that is distinct and weird: something, astronauts have described it, like "seared steak." And also: "hot metal." And also: "welding fumes."" [ref]Chestermiller said:The vapor pressure of solid iron below its melting point, in Pa, is given by the equation
log (P/Pa) = 12.106 - 21723 / (T/K) + 0.4536 log (T/K) - 0.5846 (T/K)−3
where the temperature is in degrees K.
There is some more going on than just the particle density, such as mean free path and how long before an expected collision.mfb said:3 is not 1 and not 0 either, but see above: Poisson statistics.
Or cosmic rays encountering the metal/OmCheeto said:Interesting. I'm guessing this is why: "When astronauts return from space walks and remove their helmets, they are welcomed back with a peculiar smell. An odor that is distinct and weird: something, astronauts have described it, like "seared steak." And also: "hot metal." And also: "welding fumes."" [ref]
ps. Sorry to be so late to the thread, but I just saw it today, and I'd just heard about space smelling like metal a couple of months ago, and a hypothesis regarding the evaporation of metal was the first thing that popped into my mind.
Thank you CM!
mfb said:All the vacua we are discussing here have mean free paths way larger than the size of the lab vacuum.
Interstellar space has mean free path in the range of millions to trillions of kilometers. Large compared to planets and most stars, but small compared to interstellar distances.