In response to the last few posts-
I'm not sure what ISP thrust VASMIR has actually achieved, but up to 12,000 ISP is advertised. Certainly any material in contact with the hot plasma will be eroded relatively fast. In Hall thrusters and other ion thrusters that have been deployed, the ISP up to a few thousand is the limit due to the material grids that are used for acceleration. The obvious answer is to confine the hot plasma away from the material walls with magnetic and / or electrostatic fields. In some ways it is the same idea as the virtual cathode in the Polywell.
Bussard, who was no novice at rocket science, certainly thought very high ISP efficiencies were doable.Several of his papers are listed below and there are several others on Askmar.
http://www.askmar.com/Fusion_files/Fusi ... ulsion.pdf
http://www.askmar.com/Fusion_files/From ... 0Moons.pdf
Concerning antimatter production and storage, my previous post (edited) tried to give some sense to the scales involved. An effort at increasing antimatter production by several orders of magnitude is trivial and nearly useless. Many orders of magnitude in effort is needed. Not a thousand fold increase, or even a billion fold increase, but millions of billions for a tiny ship, and a thousand times more for a larger ship. The tankage (magnetic bottle) weight and volume is tremendous also.
Storing antimatter charged particles at cryogenic temperatures would certainly greatly decrease the gyroradius at any given B field strength. But it is not a free ride. The Coulomb collision cross section goes up at ~ the second power of the inverse of the temperature. Each ExB producing collision would result in much smaller random walk gyroradius guided jumps, but these collisions would increase tremendously. Just how the balance would work out is uncertain, but I suspect it may be a minor gain or even a loss in regards to magnetic containment. So again, tremendously strong magnetic fields would be required and tremendous confinement volumes would be required for any reasonable confinement times of any reasonable antimatter amounts.
The volume has to be tremendous so that you can reach useful quantities of antimatter because the density has to be keep as low as possible. It is a trade off. As the density increases the Coulomb collisions that drive ExB drift increases squared. That is why I suggested a magnetic bottle the size of the Moon. This may be excessive though. A magnetic bottle the size of England might do provided you can generate steady state B fields of millions of Tesla, giving you modest confinement times of perhaps millions of seconds (weeks) .
There may be tricks that can be used such as using lasers or some radio waves or something to kick ExB drifting particles back towards the center. These would probable require a fair amount of energy input, but hay, you have a very big tank of antimatter as a fuel tank. Note that I have stipulated the need for the antimatter to be in the form of an ionized plasma, and this plasma would need to be nearly charge neutral, which means you would need anti protons and postrons in the mix. This begs the question, why not just make antimatter iron. It would be a solid ball and you could suspend it with magnetic fields. Problem solved. Of course anti hydrogen has been produced, but only a few atoms, to fuse this to form some solid that is magnetic is very many orders of magnitude more challenging also.
Just producing positrons would be much cheaper energetically than producing antiprotons. But you get a correspondingly smaller energy out when you annihilate it with an electron. And as I said above, if you want useful quantities of antimatter, you have to produce both. As is often pointed out with the Polywell, deviations from a neutral plasma (or solid for that matter) can only be a tiny amount. In the Polywell there is ~ 1,000,001 electrons for every 1,000,000 positively charged ions (singly charged). Much more charge imbalance drives the electrostatic potential of the plasma to stupendous levels. It might take many billions of volts of potential to contain even a milligram of anti protons in a small volume. Without that potential the particles would blast through any obtainable magnetic field ,without even needing to consider ExB drift. Look up Coulomb explosions.
There are many many orders of magnitude improvement/effort needed, not in just one system, but in possibly many systems to utilize antimatter for thrust, even for antimatter "catalyzed" fusion. Even the Entrprise doesn't use antimatter for thrust. They use "Impulse Engines" for that. The antimatter drives the Warp engines and they never (that I know) suggest how much is used, just that if they lose containement of the stored antimatter a big mess occurs.
Dan Tibbets
To error is human... and I'm very human.
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