Opinions on the Polywell fusion power system

In summary, the conversation focused on the Polywell fusion power system and the general consensus and opinions surrounding it. Participants shared their personal thoughts and criticisms on the ITER project and why particle accelerators have not been pursued as a method of fusion. They also discussed the drawbacks of the Polywell/fusor system and the advantages it may have compared to a tokamak. The potential of the Polywell to achieve high plasma density and power density was also a topic of discussion, along with the unknowns surrounding losses from cusps in the magnetic bottle. The conversation also touched on the recent research on POPS and its potential impact on the viability of IEC schemes like the Polywell.
  • #1
BrianConlee
65
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I wanted to throw out a question and see what some general consensus/opinion on the Polywell fusion power system is.

After I first read about the precursor (Farnsworth fuser) and was initially interested greatly as I had similar thoughts before really researching fusion.

Personally, I'm not a big fan of the ITER project being pursued currently... but like us all I have hope that it might work.

So, what are your thoughts, comments, criticism?

Also, why havn't particle accelerators as a method of fusion been pursued?
 
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  • #3
zz,

thanks for replying to my posts and guiding me like this. I tried doing a search on "polywell" but couldn't find any threads.

I'm a second year aerospace engineering student with a weird imagination... (don't we all have one?)

You?
 
  • #4
The polywell/fusor systems have been around a long time. They basically use an electrostatic field to accelerate ions (radially) into the center of the chamber, as opposed to magnetic compression. They have drawbacks. Neutron howizters using d+t fusion (in which deuterons are accelerated in electrostatic fields into tritiated targets) were used as neutron sources, but they have very low reaction rates, i.e. low power density.

Accelerators would be inefficient (due to scattering) since one is only looking for 1-300 keV range for fusion temperatures. On the other hand, neutral beam injectors are one method of fueling and adding energy to a magnetically confined plasma. In neutral beam injectors, atoms are stripped and the nuclei accelerated electrostatically, and then neutralized (recombined with electrons) so that they pass through the magnetic field, and the energetic neutrals collide with the plasma and become ionized while dispersing their energy. Obviously the neutral beam energy must be greater than the nominal plasma energy (temperature).

The plasma confinement system is constrained by the strength of materials, which limits the plasma pressure, which limits the plasma temperature and density by virtue of pressure being proportional to nkT, where n is the particle density, k = Boltzmann's constant, T = ion/electron temperature. Also, the plasma temperature limited in order to reduce energy losses due to cyclotron and brehmsstruhlung radiation.
 
  • #5
R. Nebel of Los Alamos has taken over the Polywell work this past summer. He's been blogging a little about his motivation. Apparently he believes Polywell is worth the time because of its advantages as practical reactor vs a tokamak, mainly in power density. He asserts the Polywell has the potential to magnetically confine electrons per
n*kBolt*Te = B**2/(2*mu0)
That is, where the electron pressure is in balance the with magnetic bottle pressure.
Ions are in turn confined electrostatically by the well set up by the energetic electrons so that the plasma is quasineutral. If Te=10^4eV, B=10T, density is 2.5e22/m**3 which is ~ 10^4 greater than ITER's planned density. Nebel is not counting on any convergence of beam ions in the center here, just a confinement slightly out of LTE. Then there are other advantages like no external neutral beam or RF heating required as for a tokamak, in a Polywell the drive energy is supplied by the electron source. The big unknown appears to be the scale of the losses from the cusps in the quasi spherical magnetic bottle.
 
  • #6
Lots of relevant discussion at Talk Polywell, in the Theory forum.

http://www.talk-polywell.org/bb/viewforum.php?f=3&sid=60b260c09d8e492fedba414b2dece5a9

Art Carlson came by and laid out a lot of objections. Nebel has replied that many of them don't apply in a non-LTE environment, and explained why he believes the others can be solved.

Here's where Carlson originally weighed in before the dicussion moved to T-P.

http://cosmiclog.msnbc.msn.com/archi...36887.aspx?p=1 [Broken]

The relatively recent POPS research that might give an IEC scheme orders of magnitude more ion density also bodes well for Polywell's chances of eventually producing an economically practical fusion reactor, something the ITER path probably can't achieve (due to the poor power density) until competing fission/fossil fuels run out (at least 1,000 years away for the former).
 
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  • #7
mheslep said:
The big unknown appears to be the scale of the losses from the cusps in the quasi spherical magnetic bottle.

This is a common point of confusion (and contention). The electron "losses" from the cusps are not losses per se, because the machine recirculates them (they do matter, because the machine must have a 1000:1 ratio inside the "bottle" versus outside). According to Bussard, the only actual losses are electron losses to unshielded areas of the machine, and cross-field transport.

What's really unknown is what losses look like at 1.5m vs 15 cm. Bussard believed they scaled as r^2, but the history of problems with predicting transport scaling in tokamaks suggest this prediction is fraught with uncertainty.
 
  • #8
TallDave said:
...
The relatively recent POPS research that might give an IEC scheme orders of magnitude more ion density also bodes well for Polywell's chances...
Yes I see comments that Nebel still thinks POPs viable, but my impression from the series of POPs paper authored by his team was no, POPs won't work in this case. The last one in series Space charge neutralization in inertial electrostatic confinement plasmas, Nebel et al, Physics of Plasmas 14, 2007
said in essence that while a steady state plasma might achieve compression in the core, oscillating plasmas (ie POPs) can not achieve high density through periodic compression:
Abstract said:
...Results indicate that there are limits on the amount of
compression that can be achieved by oscillating plasmas while simultaneously maintaining space charge neutralization and parabolic background potential.
The problem has to do with the spherical geometry chosen by a Polywell/fusor which has a work around
paper said:
What cannot be done is to simultaneously completely mitigate space charge effects with large compressions and maintain a pure harmonic-oscillator potential [POPS]in a sphere...
...It is also possible to get around the geometrical convergence limits altogether by using a cylindrical system rather than a spherical one.
But then they are back to the mirror confinement problem of the 70's.

Please comment if TD if you have other information.
 
  • #9
TallDave said:
Here's where Carlson originally weighed in before the dicussion moved to T-P.

http://cosmiclog.msnbc.msn.com/archi...36887.aspx?p=1 [Broken]

Bad link?
 
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  • #10
Oops, sorry, copied the PF abbreviation.

http://cosmiclog.msnbc.msn.com/archive/2008/06/12/1136887.aspx?p=1 [Broken]

As to POPS, not sure where that stands at the moment. IIRC the original POPS paper stated 10^4 compression was possible, and I'm not sure what the referenced limit worked out to. Even a considerably smaller improvement would be helpful I suppose.

Nebel has said ion focus probably isn't that important in a Polywell. Maybe that obviates the need for a "parabolic" potential well as mentioned above and allows POPS to work better.

Nebel recently commented on another use for resonance: removing ash.

The idea is pretty simple. You oscillate the amplitude of the virtual cathode at the resonant transit frequency for the desired ion species you want to pump energy into. It selects species by q/m. For a harmonic oscillator potential, it's pretty trivial. It's described by Mathieu equations (driven harmonic oscillators). We demonstrated this experimentally (that's what's in the Phys Rev Lett.). This will be more involved for potentials other than harmonic oscillators, but it is probably doable.

Hopefully we'll get to find out how all this works in a larger machine. The funders are reportedly reviewing the WB-7 results.
 
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  • #11
Polywell Links:

A 1 hour 15 minute YouTube Film About the Polywell with Thomas Ligon, which trys to objectively present the Pro's & Con's of the polywell:
http://www.youtube.com/watch?v=1HatEDkNnn8&feature=related

The Talk Polywell Forum, which is filled with lots of discussions:
http://www.talk-polywell.org/bb/index.php

The Polywell Wikipedia page:
http://en.wikipedia.org/wiki/Polywell

A Good Polywell Blog:
http://iecfusiontech.blogspot.com/

Bussard's Big presentation at Google:
http://video.google.com/videoplay?docid=1996321846673788606&ei=HdbkSv-QHIaIlAei4NDQCQ&q=Should+Google+go+nuclear# [Broken]

Some of the major arguements against this device working was summarized by Dr. Todd Rider in his 1994 doctoral work "Fundamental limitations on plasma fusion systems not in thermodynamic equilibrium" You can find that here:
http://dspace.mit.edu/handle/1721.1/11412

The Ligon Film does pretty good job of explaining the basic ideas, and the arguements for it working and for it not working,
 
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  • #12
FYI, having reviewed the WB-7 results, they are now building WB-8 with .8T magnets. My rough calc is it wil be expected to produce at least 8W of fusion (that's the power gain if it has the same radius as WB-7 (which produced 2 milliwatts with .1T magnets) with B^4*r*3 scaling).
 
  • #13
PolywellGuy said:
Polywell Links:

A 1 hour 15 minute YouTube Film About the Polywell with Thomas Ligon, which trys to objectively present the Pro's & Con's of the polywell:
http://www.youtube.com/watch?v=1HatEDkNnn8&feature=related

The Talk Polywell Forum, which is filled with lots of discussions:
http://www.talk-polywell.org/bb/index.php

The Polywell Wikipedia page:
http://en.wikipedia.org/wiki/Polywell

A Good Polywell Blog:
http://iecfusiontech.blogspot.com/

Bussard's Big presentation at Google:
http://video.google.com/videoplay?docid=1996321846673788606&ei=HdbkSv-QHIaIlAei4NDQCQ&q=Should+Google+go+nuclear# [Broken]

Some of the major arguements against this device working was summarized by Dr. Todd Rider in his 1994 doctoral work "Fundamental limitations on plasma fusion systems not in thermodynamic equilibrium" You can find that here:
http://dspace.mit.edu/handle/1721.1/11412

The Ligon Film does pretty good job of explaining the basic ideas, and the arguements for it working and for it not working,
PWG/TallDave: Several pop background links here. After all this time, is there any publication of actual results from the Nebel (LANL researcher) experiments that we can review?
 
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  • #14
mheslep:

Sadly, no. There is a nondisclosure agreement. We only know the Navy reviewed it and funded the next step, which costs about $12M.

We did manage to dig up the contract for WB-8. There are some details about the equipment but no WB-7 results have been released afaik.

http://www.talk-polywell.org/bb/viewtopic.php?t=1353

Most intriguing is the reference to a design for a 100MW reactor, which is to be delivered at the end of the contract. Also interesting: WB-8 will attempt to fuse p-B11, the first time this has been done in a reactor-type machine than I'm aware of (as opposed to accelerators or the Russian picosecond laser experiment).

Results may be in reviewers' hands as soon as April. When we will see them is, unfortunately, anyone's guess. We may not see any detailed results until either the project is abandoned in failure or WB-100 is producing megawatts of fusion.
 
  • #15
I find the idea intriguing, but it's some twenty years now since this magnetic wiffle ball was conceived, with no journal published results. I understand non disclosures, and the antagonism from the DoE, but that only goes so far.
TallDave said:
...We may not see any detailed results until either the project is abandoned in failure or WB-100 is producing megawatts of fusion.
I hope there are other options, as that's a rather ridiculous way to do science, imo.
 
  • #16
Bussard dying was inconvenient, too. He was planning to publish something in 2008/2009 iirc.

It is quite frustratiing to know there is experimental data out there we can't access.

It's hard to say how much of is going to remain proprietary. If it works, of course, it could be both a trillion-dollar technology and a fairly significant military advantage, so it's hard to say how open the Navy and/or EMC2 are going to be.
 
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  • #17
Polywell confinement fusion

Polywell is a plasma confinement concept that combines elements of inertial electrostatic confinement and magnetic confinement fusion, intended ultimately to produce fusion power.
The fundamental idea of the polywell device was conceived in 1983. Research was funded by US military and various small-scale prototypes were built.
Today, the development of this approach is funded by Navy but its underfunded because of wars and other projects like Tokamak. Following submission of the final WB-7 results in December 2008, Dr Richard Nebel commented that "There's nothing in there [the research] that suggests this will not work..." Dr. Bussard formed EMC2 Fusion Development Corporation, a non-profit organization, to seek funding for serious continuation of the project.

http://en.wikipedia.org/wiki/Polywell

In September 2009, the US Department of Defense announced further funding of $7,855,504 for Energy Matter Conversion Corp for research, analysis, development, and testing in support of the Plan Plasma Fusion (Polywell) Project. Efforts under this Recovery Act award will validate the basic physics of the Plasma Fusion (Polywell) concept, as well as provide the Navy with data for potential applications of polywell fusion. The project is expected to be completed by April 2011.[38]

Under development also is an "Open Source" Polywell MaGrid, to be found at the "Prometheus fusion perfection" weblog. Having demonstrated the feasibility of a Fansworth-Hirsch fusor recently, the next phase of the project is a Polywell, the parts for which have already been fabricated by 3D Rapid Prototyping.

Another particularly interesting quote from wiki:
With the success of WB-6, Bussard believed that the system had demonstrated itself to the degree that no intermediate-scale models would be needed, and noted, "We are probably the only people on the planet who know how to make a real net power clean fusion system"[8] He proposed to rebuild WB-6 more robustly to verify its performance. After conducting and publishing the results of dozens of repeatable tests, he planned to convene a conference of experts in the field in an attempt to get them behind his design. Assuming his design had been backed, the project would have immediately moved toward a full-scale demo plant. The first step in that plan was to design and build two more small scale designs (WB-7 and WB-8) to determine which full scale polyhedral potential well would be best. He wrote “The only small scale machine work remaining, which can yet give further improvements in performance, is test of one or two WB-6-scale devices but with “square“ or polygonal coils aligned approximately (but slightly offset on the main faces) along the edges of the vertices of the polyhedron. If this is built around a truncated dodecahedron, near-optimum performance is expected; about 3-5 times better than WB-6.” [12] Bussard noted that, "Thus, we have the ability to do away with oil (and other fossil fuels) but it will take 4-6 years and ca. $100-200M to build the full-scale plant and demonstrate it."[8] Bussard said "Somebody will build it; and when it's built, it will work; and when it works people will begin to use it, and it will begin to displace all other forms of energy."[22] There is some evidence of this occurring already, with at least one "Open-Source" project to replicate Dr. Bussard's work already well underway under the project title "Prometheus fusion perfection".

WB-6 prototype:
http://upload.wikimedia.org/wikipedia/en/8/8f/Polywell_WB-6_coils.jpg [Broken]

Polywell links:
http://www.emc2fusion.org/
http://www.talk-polywell.org/bb/index.php - Polywell forum
http://www.strout.net/info/science/polywell/index.html
http://prometheusfusionperfection.com/


This approach looks more promising to me than throwing money at Tokamak. What tokamak has achieved with billions, pollywell has achieved with millions, and first commercial power plants could be producing power as soon as 2020. At prometheus fusion they have already achieved fusion and are going to build a complete polywell.

It is also much smaller and lightweight, and could even be used to power naval or space ships.

Well, I am not nuclear science specialist, so guys, what do you think? Why Tokamak, and not this? :)
 
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  • #18
You can find a collection of IEC fusion papers, reports and articles in pdf format at:

http://www.askmar.com/Fusion.html
 
  • #19


ShotmanMaslo said:
This approach looks more promising to me than throwing money at Tokamak. What tokamak has achieved with billions, pollywell has achieved with millions, and first commercial power plants could be producing power as soon as 2020. At prometheus fusion they have already achieved fusion and are going to build a complete polywell.

It is also much smaller and lightweight, and could even be used to power naval or space ships.

Well, I am not nuclear science specialist, so guys, what do you think? Why Tokamak, and not this? :)
One is not a nuclear science specialist and not a nuclear engineer, but one makes a claim that some system could be used to power naval or spaceships? With what basis? I think one needs to check the accomplishments of polywells vs tokamaks.
 
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  • #20
PFX1 triple product...


Wikipedia said:
Another paper on the feasibility of IEC fusion, using the full bounce-averaged Fokker-Planck equation operator, concluded that IEC systems could produce large fusion energy gain factors (Q values). However, a deuterium-tritium reaction was necessary to minimize operating potential and Bremsstrahlung losses in order to reach large Q.

PFX1 (Penning Fusion eXperiment 1) plasma parameters:
[tex]n_{e} = 10^{18} \; \mbox{m}^{-3}[/tex]
[tex]T = 100 \; \mbox{keV}[/tex]
[tex]\tau_E = 1.7 \; \mu \mbox{s}[/tex]

WB-6 plasma parameters:
[tex]n_{e} = 10^{18} \; \mbox{m}^{-3}[/tex]
[tex]T = 10 \; \mbox{keV}[/tex]
[tex]\tau_E = 1 \; \mbox{ms}[/tex]

ITER plasma paramaters
[tex]n_{e} = 10^{20} \; \mbox{m}^{-3}[/tex]
[tex]T = 20 \; \mbox{keV}[/tex]
[tex]\tau_E = 500 \; \mbox{s}[/tex]

PFX1 triple product parameters:
[tex]n_{e} T \tau_E \leq 1.7 \cdot 10^{14} \; \mbox{keV s} / \mbox{m}^3[/tex]

WB-6 triple product parameters:
[tex]n_{e} T \tau_E \leq 10^{16} \; \mbox{keV s} / \mbox{m}^3[/tex]

ITER triple product parameters:
[tex]n_{\rm e} T \tau_E \leq 10^{24} \; \mbox{keV s} / \mbox{m}^3[/tex]

The triple product required for D-T ignition is:
[tex]n_{e} T \tau_E \ge 3.75 \cdot 10^{21} \; \mbox{keV s} / \mbox{m}^3[/tex]

Reference:
http://en.wikipedia.org/wiki/Lawson_criterion" [Broken]
http://en.wikipedia.org/wiki/Polywell" [Broken]
http://ftp.aip.org/epaps/phys_plasmas/E-PHPAEN-7-935005/PFXI%20Proposal.pdf" [Broken]
http://en.wikipedia.org/wiki/ITER" [Broken]
https://www.physicsforums.com/showpost.php?p=2386385&postcount=9"
 
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  • #21


Astronuc said:
One is not a nuclear science specialist and not a nuclear engineer, but one makes a claim that some system could be used to power naval or spaceships? With what basis? I think one needs to check the accomplishments of polywells vs tokamaks.

The main reason is scaling compared to Tokamak:
There are 2 scaling factors involved in this type of device: the power output scales as the 7th power of the size, and the power gain as the 5th power of the size. Simply if you double the size of the magnets you get 128X the output.

Polywell Scaling theory says magnets need only be 3 meters, in a concrete building 30 ft by 30 by 30. for a PB-11 1000MW unit. Considering the ITER site is 100's of acres...

Is this false? Got it from here http://www.linkedin.com/answers/Sustainability/energy-development/SUS_ENE/483242-46796005

Considering the money and research time put into Polywells vs. Tokamaks, current accomplishments comparison is somewhat irrelevant, isn't it? :)
 
  • #22


ShotmanMaslo said:
The main reason is scaling compared to Tokamak:

There are 2 scaling factors involved in this type of device: the power output scales as the 7th power of the size, and the power gain as the 5th power of the size. Simply if you double the size of the magnets you get 128X the output.

Polywell Scaling theory says magnets need only be 3 meters, in a concrete building 30 ft by 30 by 30. for a PB-11 1000MW unit. Considering the ITER site is 100's of acres...
Is this false? Got it from here http://www.linkedin.com/answers/Sustainability/energy-development/SUS_ENE/483242-46796005


Considering the money and research time put into Polywells vs. Tokamaks, current accomplishments comparison is somewhat irrelevant, isn't it? :)
No. Show me the proof, not some unsubstantiated claim from linkedin.
 
  • #23
B^4*R^3 power scaling is pretty standard. You would expect a high-beta device to be smaller... if it works. The question is the loss scaling.

The problem in IEC has always been confinement. Does the wiffle-ball effect in Polywells lead to workable loss scaling? WB-8 will probably shed some light when results are due in Apr 2009, since B has increased by a factor of 8 over WB-7.

BTW, "ignition" is not an especially meaningful concept in Polywells. They don't ignite (fusion products are not used to heat the plasma) and require constant electron drive input (probably about 10MW for the envisioned 100MW WB-9 reactor). Break-even could be defined as the point where the reactor produces more electric power than it requires to operate.
 
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  • #24


ShotmanMaslo said:
Considering the money and research time put into Polywells vs. Tokamaks, current accomplishments comparison is somewhat irrelevant, isn't it? :)

Not necessarily so, I wish I had the proper citation, Dr Nebel loved to comment how Polywells' plasma density or sumsuch thing was superior to a Tokamak. A proper search at talk-polywell would reveal the quote.

In fact the comparison of accomplishments is most relevant, and I predict will become more so as research continues. I predict in 20 months Polywell will be at a development stage equal to or more advanced than the Tokamak. In fact if the current trend continues Polywell will be showing Net power from the PB-11 reaction, before the ITER gets fully warmed up.
 
  • #25
TallDave said:
WB-8 will probably shed some light when results are due in Apr 2009,

Dave, I'm sure April 2009 is a typo.
 
  • #26


Astronuc said:
No. Show me the proof, not some unsubstantiated claim from linkedin.

And until some legit publication is made, or public demo, there has been, will be, no proof in spite of some well meaning efforts.
 
  • #27


RogerFox said:
Not necessarily so, I wish I had the proper citation, Dr Nebel loved to comment how Polywells' plasma density or sumsuch thing was superior to a Tokamak. A proper search at talk-polywell would reveal the quote.

In fact the comparison of accomplishments is most relevant, and I predict will become more so as research continues. I predict in 20 months Polywell will be at a development stage equal to or more advanced than the Tokamak. In fact if the current trend continues Polywell will be showing Net power from the PB-11 reaction, before the ITER gets fully warmed up.
So by October 2011, one predicts that a Polywell will be generating net power using the p-B11 reaction? That would be great!
 
  • #28
I had no idea the ITER was 10 to 15 yrs ahead of schedule...my bad
 
  • #29
RogerFox said:
I had no idea the ITER was 10 to 15 yrs ahead of schedule...my bad
Actually, I think it is behind schedule.
 
  • #30
RogerFox said:
Dave, I'm sure April 2009 is a typo.

Oops, thanks should be 2010 of course.

So by October 2011, one predicts that a Polywell will be generating net power using the p-B11 reaction? That would be great!

Best case scenario is 2015. Most likely they would try a D-D first, but if WB-8 is promising enough and there's enough interest simultaneous D-D/p-B-11 projects aren't impossible.

ITER is likely to work, but it's going to take decades and barring major advances tokamaks won't be economically viable until all the fission fuels run out, which is 1,000 to 250,000 years away.
 
  • #32
Liljencroowna said:
Update:

http://www.emc2fusion.org/
http://cosmiclog.msnbc.msn.com/archive/2010/03/23/2237165.aspx [Broken]
http://www.talk-polywell.org/bb/viewtopic.php?t=2037

That's about as minimal an update as minimal can get. They added the words 'validate and extend' to their 1-page website? No hint of results or a paper? The interview says, some 20 years after the origination of Bussard's basic confinement concept, that he wants a few $100k to "do some basic physics on this"?

Nebel deserves credit for being disciplined about not releasing any idle speculation whatsoever, but after some time he's also expected to explain why he hasn't released results on the work he has done.
 
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  • #33
Yes, he could at the very least say if it's working the way it's predicted. I think it would be good for everyone if they released SOME data - less speculation amongst us spectators. Of course one can draw the conclusion that it's at least still on (and did not fail - terribly), otherwise the Navy wouldn't fund it.
 
  • #34
Well, it's DOD not DOE. He is under a gag order. Someone over at T-P even put together a FOIA request, which was denied.

WB-7 did validate WB-6 results, according to Rick. Here's what's ahead:

CLIN 0001 - 30 Apr 2010 (= plasma wiffleball 8 ) - Completion of device build.
CLIN 0002 - 30 Apr 2011 (= Data) - Completion of WB8 testing
CLIN 0003 - 31 Oct 2011 (= Optional WB 8.1) - Completion of optional device build
CLIN 0004 - 31 Oct 2012 (= Optional Data) - Completion of optional device testing

The optional WB-8.1 would attempt to fuse p-B11, a first in reactor-type fusion machines afaik. If they pick up this option next Apr we can infer WB-8 results weren't a total disaster.

At the Oct 2012 deadline there is an option for the Navy to fund the $200M WB-D (or WB-9) prototype reactor. We will know if this happens that the loss scaling was something friendly, like the B^.25 * r^2 Bussard claimed. If it doesn't happen, there's a good chance we will see some data.

My rough estimate is WB-8 should produce something around 500W of fusion, hopefully with current not greatly exceeding that of WB-7 (need to do the math on this). It has .8T magnets and is about 5/3 larger than WB-7, which produced about 2 mw of fusion with .1T magnets.
 
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  • #35
TallDave said:
Well, it's DOD not DOE. He is under a gag order. ...
What's the source for that? I've never read Nebel saying he was gagged by contract, and I've read most of his posts at TP.
 
<h2>1. What is the Polywell fusion power system?</h2><p>The Polywell fusion power system is a type of fusion reactor that uses a magnetic confinement method to contain and heat plasma to temperatures high enough for fusion to occur. It was first proposed by physicist Robert Bussard in the 1980s and has since been studied by various researchers and companies.</p><h2>2. How does the Polywell fusion power system work?</h2><p>The Polywell fusion power system uses a spherical vacuum chamber surrounded by electromagnets to create a magnetic field. This field contains and heats up a cloud of electrons and ions, also known as plasma, to temperatures of millions of degrees. The high temperatures and confinement allow for fusion reactions to occur, releasing large amounts of energy.</p><h2>3. What are the advantages of the Polywell fusion power system?</h2><p>The Polywell fusion power system has several potential advantages over other fusion reactor designs. These include a simpler and more compact design, the ability to use inexpensive fuels such as boron and hydrogen, and the potential for a high power-to-weight ratio. It also produces relatively little radioactive waste compared to traditional nuclear power plants.</p><h2>4. What are the challenges of the Polywell fusion power system?</h2><p>One of the main challenges of the Polywell fusion power system is achieving the necessary temperatures and confinement required for fusion to occur. This has been a major obstacle for all fusion reactor designs. Additionally, the technology is still in its early stages of development and has not yet been proven to be a viable source of energy.</p><h2>5. Is the Polywell fusion power system a feasible solution for clean energy?</h2><p>While the Polywell fusion power system shows promise, it is still in the research and development phase and has not yet been proven to be a feasible solution for clean energy. Many technical and engineering challenges still need to be addressed before it can be considered a viable option for commercial use. However, continued research and advancements in the technology may make it a viable solution in the future.</p>

1. What is the Polywell fusion power system?

The Polywell fusion power system is a type of fusion reactor that uses a magnetic confinement method to contain and heat plasma to temperatures high enough for fusion to occur. It was first proposed by physicist Robert Bussard in the 1980s and has since been studied by various researchers and companies.

2. How does the Polywell fusion power system work?

The Polywell fusion power system uses a spherical vacuum chamber surrounded by electromagnets to create a magnetic field. This field contains and heats up a cloud of electrons and ions, also known as plasma, to temperatures of millions of degrees. The high temperatures and confinement allow for fusion reactions to occur, releasing large amounts of energy.

3. What are the advantages of the Polywell fusion power system?

The Polywell fusion power system has several potential advantages over other fusion reactor designs. These include a simpler and more compact design, the ability to use inexpensive fuels such as boron and hydrogen, and the potential for a high power-to-weight ratio. It also produces relatively little radioactive waste compared to traditional nuclear power plants.

4. What are the challenges of the Polywell fusion power system?

One of the main challenges of the Polywell fusion power system is achieving the necessary temperatures and confinement required for fusion to occur. This has been a major obstacle for all fusion reactor designs. Additionally, the technology is still in its early stages of development and has not yet been proven to be a viable source of energy.

5. Is the Polywell fusion power system a feasible solution for clean energy?

While the Polywell fusion power system shows promise, it is still in the research and development phase and has not yet been proven to be a feasible solution for clean energy. Many technical and engineering challenges still need to be addressed before it can be considered a viable option for commercial use. However, continued research and advancements in the technology may make it a viable solution in the future.

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