93143 wrote:It sounds like you're operating in the wrong regime.
higher net charge per coil current leaks more electrons, while a lower ratio has smaller net charge and thus shallower potential wells. and i would presume "right" means highest power out per power in. though i'm just judging visually right now. we'll see how it looks once i add the phase space view.
You can't just start the electrons at zero and expect a wiffleball to form.
duh. you need a mag field for that.
They'll just stay in the centre, constrained by the magnetic field.
and that's a problem?
To form a wiffleball, you need a lot of fast charged particles to push the magnetic field back. Only after the plasma charge density has reached equilibrium will the electrons be slow near the centre.
incorrect.
Also remember that the net charge is only about 1e-6 of the total charge count in the plasma (I believe that was for a WB-6-class machine). You need a lot of fast electrons and ions (they should be fast in different regions, but proper injection should handle that), with a very small excess of electrons; the whole plasma contributes to the diamagnetic effect that forms the wiffleball.
while some electrons will inevitably be fast, preferablly they are cold, esp. in the center. the opposite holds true for the ions.
The electrons guns are just thermionic emitters; they drop the electrons into the positive potential well created by the magrid charge,
the potential well is negative
which is where the electrons get their energy
you mean they use the charge on the magrid to accelerate. yes that's one way to get the electrons into the center - to make them climb the negative potential well.
and why the whole thing works.
no, that is not what makes it work.
And you shouldn't need all that much accuracy to get the electrons inside; they should just spiral down into the cusps (using a physically realistic density, or at least collision rate, may be helpful in getting them off the field lines). If you try to circumvent this by starting electrons at almost zero in the centre, you're missing the whole physics of how they got that way, which is actually very important, and your simulation won't recover that for you.
i have simulated the brute force approach, and while in time it does start to form a wiffleball -- or what you would argue is not a wiffleball -- it is very slow and VERY inefficient. while it's true that you don't "need" to aim your eguns for the center, you will get a much deeper potential well and fewer electrons thermalized and lost per electron you fire in if you do.
I should also note that the magrid doesn't have a constant charge - it has a constant potential. The charge on it increases to maintain the potential difference between the magrid and the surrounding components (e.g. the electron emitters) as the negative charge of the wiffleball builds up.
as far as my simulation goes, to calculate the eelectric field around each wire segment, i need to start with coloumbs per meter, just like to do the same for each particle i need to know it's charge in coloumbs.
if i'll need to vary this throughout the sim, well i suppose i shall get a clearer picture once i get my phase space view up and running. but unitl then, well, it's not really a big deal.
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Very interesting simulation, though. I wish I had the time to do some simulating of my own (I have a couple of prototypes in Matlab sitting around), but I'm quite busy with my Ph.D. research right now...
thanks. i plan on making it even more interesting
