The numbers I used were arbitarily chosen for convience (rounded numbers). B- fields in the 3 Tesla range because I understand that that is doable with cooled copper (Once magrid crossection volume is large enough to contain alot of windings along with cooling plumbing and insulating structures) To get 10 Tesla, I'm sure superconducters are required. Also, M. Simon's proposal to use MRI magnets are in the 3 Tesla range. Size was chosen to get a round number and to still possibly be squeezed into the current 1 meter vacuum chamber that EMC2 is using, and yet be large enough to possibly get meaningfull size scaling compared to the 30cm WB6 and 30cm (or 35cm?) of WB7.
I briefly considered adding potential POPS gains but I have seen gains mentioned from ~ 4X to a 1000X, so I chose to consider it as frosting on the cake, and not nessisary to develope my optomistic projections. I understand that my numbers are already streaching the engeenering limits of thermal wall loading, vacuum capabilities, etc. Or, even with my nonmaximized numbers, the performance is already limited by engeening concerns, ie- there is alot of wiggle room in the physics ( or as A. Carlson said, lots of room on the pessimistic side of the predictions, but hopefully not to the extent that requirements ballon to such proportions as the Tokamacs need to break even).
Concerning Chrismb's concern about sputtered products contaminating the reaction space, so long as the sputtered products are mostly ionized, they would find it very difficult to enter the Magrid (positive ions repelled from the magrid, negative ions tangled up in the collection grid (?)), so contamination will be minimal. The concern would be vacuum pumping of any sputtered or recombined neutrals before they built up to levels which would cause arcing. At these levels the neutrals, even if they penitrated the magrid, would have a density much below (1000X?) the fuel ion density ( due to the Wiffleball traping factor and even without concidering any convergence of the ions to the central core.) The alphas (or P,He3, and H3 fusion products from D-D fusion) could all be slowed to slow speeds while thie energy is harvested, before they hit a wall. I don't know why the different energies would be a show stopper. After all, a mass spectrometer can seperate and collect widely different energy charged particles. Weather this can be done in a Polywell enviornment is debatable, but if almost all of the charged fusion products exit through cusps the engeenering challenge will be simplified.
[EDIT] ps: Is the limit for MHD stability an exactly spherical surface or almost a spherical surface approached from the convex side? I ask because I wonder if I should persue my monople research in order to develope a truely spherical machine like a government official believed the Polywell was claimed to be?
Dan Tibbets
To error is human... and I'm very human.