Can someone with more taught plasma knowledge than me just fix up my understanding of the magnitude of magnetic pressure in the devices we often discuss?:
magnetic pressure is = B^2/2u[o]
and 'gas pressure' is = n.k.T
So if we have a tokamak or Polywell with, say, 5T and it has a volume with n=1e19 (well, this is ~how much a tok runs with, so I understand) then we get a magnetic pressure of 5^2/2.(1.26e-6) = 10MPa, which is 100atm!?
Is that right? Seems an awfully high figure to me in a vacuum chamber?!
And if we put it into the gass pressure eqn with n=1e19, then we get a T of 70GK (6.5MeV).
So shouldn't a 5T field be enough to contain a 6.5MeV plasma? If those magnitudes are correct for magnetic pressure I don't see how a measley 10keV plasma is remotely poorly confined! [What] am I missing [/something] here?
Beta/magnetic pressure - the equations with real numbers in.
I have seen betas as high as .1 quoted for toks. I'm not sure if that was actuals or some time real soon now.chrismb wrote:If that's a reasonable beta then I guess it's in the ball park. (The tok shot plots usually show n as units of 1e19, rather than over 1e20, though)
I thought beta was higher... hmmm...
Engineering is the art of making what you want from what you can get at a profit.
Re: Beta/magnetic pressure - the equations with real numbers
chrismb wrote:Can someone with more taught plasma knowledge than me just fix up my understanding of the magnitude of magnetic pressure in the devices we often discuss?:
magnetic pressure is = B^2/2u[o]
and 'gas pressure' is = n.k.T
So if we have a tokamak or Polywell with, say, 5T and it has a volume with n=1e19 (well, this is ~how much a tok runs with, so I understand) then we get a magnetic pressure of 5^2/2.(1.26e-6) = 10MPa, which is 100atm!?
Is that right? Seems an awfully high figure to me in a vacuum chamber?!
And if we put it into the gass pressure eqn with n=1e19, then we get a T of 70GK (6.5MeV).
So shouldn't a 5T field be enough to contain a 6.5MeV plasma? If those magnitudes are correct for magnetic pressure I don't see how a measley 10keV plasma is remotely poorly confined! [What] am I missing [/something] here?
Noted the high quoted pressure. It occurs to me that comparing pressure with density is missleading. The density of air (one atmosphere ) is standardized at a set temperature. One mole of air= 22.4 liters at STP conditions. A mole of gas at a Maxwellian temperature of ~ 5000 eV (550,000,000 degrees C) would exert a proportionatly higher pressure (I'm too lazy to look it up and calculate it), but I suspect the pressure would be huge. So it may not be surprizing that a very hot gas, despite a low density, would generate a high pressure at high temperatures. If a strong perminate magnet of perhaps a few hundred Gauss can suport weights of many pounds, the lifting (or pushing) power of a magnet of several Tesla could resist a considerable gas pressure (pounds/ sq. inch).
Dan Tibbets
To error is human... and I'm very human.
Re: Beta/magnetic pressure - the equations with real numbers
Assuming ideal gas law, which DOESN'T apply, but let us look at it anyway:D Tibbets wrote: Noted the high quoted pressure. It occurs to me that comparing pressure with density is missleading. The density of air (one atmosphere ) is standardized at a set temperature. One mole of air= 22.4 liters at STP conditions. A mole of gas at a Maxwellian temperature of ~ 5000 eV (550,000,000 degrees C) would exert a proportionatly higher pressure (I'm too lazy to look it up and calculate it), but I suspect the pressure would be huge. So it may not be surprizing that a very hot gas, despite a low density, would generate a high pressure at high temperatures. If a strong perminate magnet of perhaps a few hundred Gauss can suport weights of many pounds, the lifting (or pushing) power of a magnet of several Tesla could resist a considerable gas pressure (pounds/ sq. inch).
Pv=nRT (or some such varient). Given everthing the same except the T,
P = X*T where X represents evcerything else
T@5000eV ~2,000,000 times T@STP ((500,000,000/250)
Thus, P ~2E6 bar. As you say... HUGE, but not real
