Polywell

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WB-6, assembled
WB-6, assembled

The polywell is a plasma confinement concept that combines elements of inertial electrostatic confinement and magnetic confinement fusion, intended ultimately to produce fusion power. The name polywell is a portmanteau of "polyhedron" and "potential well."

The polywell consists of electromagnet coils arranged in a polyhedral configuration, within which the magnetic fields confine a cloud of electrons. This configuration traps electrons in the middle of the device which produces a "quasi-spherical" negative electric potential and is used to accelerate and confine the ions to be fused. It was developed by Robert Bussard under a US Navy research contract as an improvement of the Farnsworth-Hirsch fusor.

Contents

[edit] Design

[edit] Problems with Farnsworth-Hirsch fusors

A traditional Farnsworth-Hirsch fusor consists of a vacuum chamber containing a positively charged outer grid and a negatively charged inner grid within; essentially a large vacuum tube with spherical grids. Fusible atomic nuclei are injected as ions into the system, repelled by the outer grid, and accelerated toward the inner grid. Most of the time, the ions miss the grid, but occasionally, given long enough, nuclei strike either the grid or another high-energy nucleus. Most strikes with other nuclei do not result in fusion, but occasionally fusion results. On a miss, the nuclei move outwards, are repelled by the outer grid again, and return through the core. Without the motion of electrons and magnetic fields, there are no synchrotron losses and low levels of bremsstrahlung radiation.[citation needed]

The fundamental problem with this traditional system is with the grid itself. Far too often, nuclei strike the grid. This damages the grid, wastes the energy that went into ionizing and accelerating the particle, and most critically, heats the grid. Even if the former problems were not critical, having a fine mesh grid in a reactor producing enough power to be used as a power plant would almost certainly mean that it would be rapidly vaporized.

[edit] The polywell approach

Like the fusor, the polywell confines positive ions through their attraction to negatively charged electrons, the difference being that while in the fusor, the negative charges reside on a solid-state grid, in the polywell, they are confined to the inner region of the reactor by magnetic fields. The reactor volume is defined by the coils producing the magnetic field, rather than by electrically charged grids. The advantage of coils over grids is that the magnetic fields produced by the coils also help protect them from the energetic electrons and ions. On the other hand, the polywell has electrons and ions existing in the same volume, reintroducing the Bremsstrahlung that the fusor can avoid.

The magnetic field is produced by a polyhedral arrangement of coils, all pointing toward (or all away from) the center. The magnetic field vanishes at the center, and the magnetic flux that enters the volume through the coils leaves it again through the spaces between the coils. Thus the electrons are confined to the central volume by a magnetic mirror with a large field ratio, and all the cusps are points (rather than lines). Ions can be added to produce a plasma, but there must always be more electrons than ions in order to maintain the potential well.[1][2] While this concept, in contrast to the original fusor, uses magnetic fields, they do not need to confine nuclei — only electrons, which are orders of magnitude simpler to confine.[3][4][5]

The applicable polyhedra are those which have an even number of faces at each vertex, so that the poles of the solenoids can alternate. Infinitely many polyhedra satisfy this property, for instance all antiprisms, 2n-agonal bipyramids, and all rectified (fully truncated) polyhedra. As can be seen in the picture, WB-6 is a cuboctahedron. Bussard's planned WB-8 would be an icosidodecahedron. These geometries have several interesting properties. The shape of the magnetic potential well is the dual polyhedron of the machine. Each polyhedron could be constructed two different ways from circular coils, or the edges of the polyhedron could be wired directly as with Bussard's NPG polyhedral grid (there is a eulerian path because all vertices are even).

Despite initial difficulties in spherical electron confinement, at the time of the 2005 research project's termination, Bussard had reported a neutron rate of 109 per second running D-D fusion reactions at only 12.5 kV (based on detection of three neutrons per test,[6] giving a wide confidence interval). He claimed that the fusion rate achieved by WB-6 is roughly 100,000 times greater than that Farnsworth managed to achieve at similar well depth and drive conditions.[7][8] Researchers at the University of Wisconsin-Madison have also claimed a neutron rate of up to 5x109 per second at voltages of 120 kV.[9]

He claimed that, assuming superconductors for the coils, the only significant losses are electron losses, meaning that the fusion power output of the device scales as the seventh power of the radius, and the energy gain scales as the fifth power. While Bussard had not publicly documented the physical reasoning underlying this estimate,[10] if true, it would enable a model only ten times larger to be useful as a fusion power plant.[11]

[edit] Comparison to conventional confinement concepts

The polywell is related to various other plasma confinement concepts, but differs markedly from all of them. It is most closely related to the fusor, which, like the polywell, confines ions by an inwardly directed electric field and requires a grid of solid-state electrodes within the plasma vessel. Both concepts intend to operate with a highly non-thermal, ideally mono-energetic, distribution of ion energies. If the ion energies can be held near the optimum value, the fusion rate for a given plasma pressure can be a few times higher than the maximum rate possible for ions with a thermal distribution. On the other hand, collisions and collective instabilities have a tendency to restore a thermal distribution, so that it generally costs power to maintain a mono-energetic distribution.

The polywell differs from the fusor in that the electrons are magnetically confined, so that it is also related to magnetic confinement fusion, most closely to magnetic mirrors. In common with magnetic mirrors is the field minimum in the central region, the confinement (in part) by the mirror effect, and (at least to some extent) a non-thermal distribution of the electron energies. In some mirror configurations, the field in the center is a minimum in every direction, as it is in the central region of a polywell. The magnetic field in such a case is said to have "good curvature" because a certain class of fluctuations are stable in a plasma contained by such a field. In contrast to mirror machines, the polywell does not just have a minimum in the field strength in the center, the field vanishes entirely there. Also the polywell does not have a magnetic axis, but rather a polyhedral symmetry.

The most successfully developed plasma confinement concept at this time is the tokamak. A net power fusion reactor based on the tokamak concept would certainly be a large and complex machine. The advocates of the polywell predict that a polywell reactor of similar power would be much smaller and simpler. The tokamak has a toroidal geometry with nested flux surfaces, so that both ions and electrons can only be lost by transport across magnetic field lines (primarily as a result of instabilities with very short wavelengths). The confinement of particles in a polywell is more complex, involving both magnetic and electric fields, transport of particles both across and along magnetic field lines, and different processes for the ions than for the electrons.

[edit] Possibility of net power

Bussard believed that this device can run with net energy production on boron-11 and proton fuel. Controversies exist over whether the ions and electrons will thermalise and whether bremsstrahlung losses will emit more energy in an unrecoverable form than can be produced by the fusion reaction.

Todd Rider calculates that bremsstrahlung losses with this fuel relative to the fusion production will be 1.20:1.00.[12] Bussard said that his calculation of the losses are about 5% of this, and therefore, greater gains than unity are possible.[13]

According to Bussard the high speed and therefore low cross section for Coulomb collisions of the ions in the core makes thermalizing collisions very unlikely, while the low speed at the rim means that thermalization there has almost no impact on ion velocity in the core.[11]

Another paper on the feasibility of IEC fusion, using the full bounce-averaged Fokker-Planck equation operator, concluded that IEC systems could produce large Q values. However, a deuterium-tritium reaction was necessary to minimize operating potential and Bremsstrahlung losses in order to reach large Q.[14]

[edit] History

WB-2
WB-2
WB-3
WB-3
WB-6 during assembly with coils showing
WB-6 during assembly with coils showing

The fundamental idea of the polywell device was conceived in 1983.[15] Research was funded by the Department of Defense since 1987, and the United States Navy began providing low-level funding to the project in 1992.[16] Bussard, who had formerly been an advocate for Tokamak research, in 1995 sent a letter to the United States Congress stating that he had only supported Tokamaks in order to get fusion research sponsored by the government, but he now believed that there are better alternatives to Tokamaks.

Polywell models were produced through an iterative process, ranging from WB-1 through WB-6 (with WB-7 and 8 planned, but not yet constructed). Early designs consisted of tightly welded stainless steel cubes of electromagnets, wound on square-cross section spools. These designs suffered from "funny cusp" losses at the joints between magnets, and from the magnetic field clipping the corners of the spools. The losses into the metal severely hurt their performance, leading to lower electron trapping performance than predicted. Later designs (starting with WB-6) began spacing electromagnets apart instead of touching, and changed to circular cross sections instead of square, reducing the metal surface area unprotected by magnetic fields. These changes dramatically improved system performance, leading to a great deal of electron recirculation and the confinement of electrons into a progressively tighter core. Until 2005 all of the reactors have been 6-magnet designs built as a cube (or more specifically as a truncated cube). WB-8 is planned to be a higher-order polyhedron, with 12 electromagnets.

Funding became tighter and tighter. According to Bussard, "The funds were clearly needed for the more important War in Iraq."[8] An extra $900k of Office of Naval Research funding allowed the program to continue long enough to reach WB-6 testing on November 2005. The last-produced model, WB-6, produced a fusion rate of 109 per second. Drive voltage on the WB-6 tests was about 12.5 kV, with a resulting potential well depth of about 10 kV, thus deuterons arriving in the center of the machine will have a kinetic energy of 10 keV. By comparison, a Fusor running deuterium fusion at 10 kV would produce a fusion rate difficult to detect at all. Hirsch reported a fusion rate this high only by driving his machine to 150 kV and by using deuterium-tritium fusion (a much easier reaction). While the pulses of operation in WB-6 were sub-milliseconds, Bussard felt the conditions should represent steady state as far as the physics are concerned. Most critically, the models of the system indicate that a full-sized model, costing approximately $150-200M (depending on the fuel), should be an effective power plant, producing notably more energy than it consumes. A last-minute test of WB-6 ended prematurely when the insulation on one of the hand-wound electromagnets burned through, destroying the device. With no more funding during 2006 and partly 2007, the project's military-owned equipment was transferred across town to SpaceDev, which also hired three of the team's researchers.[8]

After the transfer, Bussard tried to attract new investors, giving talks trying to raise interest in his design. A talk at Google headquarters had the title, "Should Google Go Nuclear?"[17] An informal overview of the last decade of work was presented at the 57th International Astronautical Congress in October 2006.[11] Bussard's polywell work won an "Outstanding Technology of the Year" award from the International Academy of Science in 2006 [1].

In August 2007, EMC2 received a $2M U.S. Navy research contract to continue the reactor development.[18][19] Following Bussard's death in October, 2007, Richard Nebel took the helm on the polywell design team at EMC2, and the latest experimental device, WB-7, achieved "1st plasma" in early January, 2008.[20] Depending on the results of ongoing experiments, the research could continue in pursuit of the final full-sized model.

[edit] Current/future work

Bussard believed that the system had demonstrated itself to the degree that no intermediate-scale models will 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"[7] Since August 2007 with a new U.S Navy research contract, he intended to build two more designs to determine what full scale model would be best (WB-7 and WB-8), and with them, conduct and publish the results of dozens of repeatable tests. He then planned to convene a conference of experts in the field in an attempt to get them behind his design. Assuming his design would have been backed, the project would have immediately moved to a full-scale demo plant construction.

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."[7] A web site registered to Robert Bussard and EMC2 Fusion Development Corporation, "a charitable research and development organization", was created to solicit donations to enhance further research.

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."[21]

Dr. Bussard passed away on October 6, 2007. His work is being continued by the staff of physicists he was able to assemble at EMC2. Dolly Gray, who co-founded EMC2 with Bussard in 1985, and served as its president and CEO, has helped assemble the small team of scientists in Santa Fe. The group includes Rick Nebel, Jaeyoung Park, both physicists on leave from LANL; Mike Wray, the physicist who ran the key 2005 tests; and Kevin Wray, who is the computer specialist for the operation.

The latest device, WB-7, was constructed at a machine shop in San Diego and shipped to Santa Fe, where a small group of scientists have set up a testing facility and are currently running experiments. The device, like previous ones, was designed by engineer Mike Skillicorn.

Suggestions have been made to have a multi-agency review of the results and schematics to encourage timely public release of all findings and documentation.

[edit] References

  1. ^ US4,826,646 (PDF version) (1989-05-02) Robert W. Bussard Method and apparatus for controlling charged particles 
  2. ^ US5,160,695 (PDF version) (1992-11-03) Robert W. Bussard Method and apparatus for creating and controlling nuclear fusion reactions 
  3. ^ Krall, Nicholas A.; Bussard, Robert W. (1995). "Forming and maintaining a potential well in a quasispherical magnetic trap". Physics of Plasmas 2 (1): 146–158. doi:10.1063/1.871103. ISSN 1070664x. 
  4. ^ Bussard, Robert W. (1991). "Some physics considerations of magnetic inertial-electrostatic confinement ;A new concept for spherical converging-flow fusion". Fusion Technology 19 (2): 273–293. ISSN 07481896. 
  5. ^ Krall, Nicholas A. (1992). "The Polywell ;A spherically convergent ion focus concept". Fusion Technology 22 (1): 42–49. ISSN 07481896. 
  6. ^ EMC2 Report. Final Successful Tests of WB-6. Retrieved on 2007-11-08.
  7. ^ a b c Robert W. Bussard (2006-03-29). Inertial Electrostatic Fusion systems can now be built. fusor.net forums. Retrieved on 2006-12-03.
  8. ^ a b c SirPhilip (posting an e-mail from "RW Bussard") (2006-06-23). Fusion, eh?. James Randi Educational Foundation forums. Retrieved on 2006-12-03.
  9. ^ [http://iec.neep.wisc.edu/results.php UW-IEC Project
  10. ^ Possibly he was assuming that the ion energy distribution is fixed, that the magnetic field scales with the linear size, and that the ion pressure (proportional to density) scales with the magnetic pressure (proportional to B²). The R7 scaling results from multiplying the fusion power density (proportional to density squared, or B4) with the volume (proportional toR³). On the other hand, if it is important to maintain the ratio of the Debye length or the gyroradius to the machine size, then the magnetic field strength would have to scale inversely with the radius, so that the total power output would actually be lower in a larger machine.
  11. ^ a b c "The Advent of Clean Nuclear Fusion: Super-performance Space Power and Propulsion", Robert W. Bussard, Ph.D., 57th International Astronautical Congress, October 2-6, 2006
  12. ^ Fundamental limitations on fusion systems not in equilibrium p161
  13. ^ "Bremsstrahlung Radiation Losses in Polywell Systems", R.W. Bussard and K.E. King, EMC2, Technical Report EMC2-0891-04, July, 1991
  14. ^ "Energy gain calculations in Penning fusion systems using a bounce-averaged Fokker–Planck model", Chacon, Barnes, Miley and Knoll, Phys. Plasmas 7, 4547 (2000); DOI:10.1063/1.1310199
  15. ^ Posted to the web by Robert W. Bussard (February 2006). A quick history of the EMC2 Polywell IEF concept (Microsoft Word document). Energy/Matter Conversion Corporation. Retrieved on 2006-12-03.
  16. ^ Posted to the web by Robert W. Bussard. Inertial electrostatic fusion (IEF): A clean energy future (Microsoft Word document). Energy/Matter Conversion Corporation. Retrieved on 2006-12-03.
  17. ^ Dr. Robert Bussard (lecturer) (2006-11-09). Should Google Go Nuclear? Clean, cheap, nuclear power (no, really) (Flash video). Google Tech Talks. Google. Retrieved on 2006-12-03.
  18. ^ Funding Continues for Bussard's Fusion Reactor. New Energy and Fuel (2007-08-27). Note that this source is a blog and not necessarily reliable.
  19. ^ William Matthews (2007-11-06). Fusion Researcher Bussard Dies at 79 (webpage). Online article. Defencenews.com. Retrieved on 2007-11-06.
  20. ^ Strange Science Takes Time. MSNBC (2008-01-09).
  21. ^ The Space Show. Hosted by Dr. David Livingston. 2007-05-08. No. 709 with guests Dr. Robert W Bussard, Thomas A Ligon.

[edit] External links

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