Systems and methods for reducing undesired eddy currents

Information

  • Patent Grant
  • 10418170
  • Patent Number
    10,418,170
  • Date Filed
    Thursday, November 9, 2017
    7 years ago
  • Date Issued
    Tuesday, September 17, 2019
    5 years ago
  • Inventors
    • Rath; Nikolaus (Foothill Ranch, CA, US)
  • Original Assignees
  • Examiners
    • Ferguson; Dion
    • Sathiraju; Srinivas
    Agents
    • One LP
Abstract
Systems and methods to reduce the amplitude of undesirable eddy currents in conducting structures, e.g., induced by the translation of an FRC into a confinement chamber, while leaving beneficial eddy currents unaffected. This is achieved by inducing opposing currents in the same conducting structures prior to plasma translation into the confinement chamber.
Description
FIELD

The subject matter described herein relates generally to magnetic plasma confinement systems and, more particularly, to systems and methods that facilitate cancellation of undesired eddy currents.


BACKGROUND

The Field Reversed Configuration (FRC) belongs to the class of magnetic plasma confinement topologies known as compact toroids (CT). It exhibits predominantly poloidal magnetic fields and possesses zero or small self-generated toroidal fields (see M. Tuszewski, Nucl. Fusion 28, 2033 (1988)). The traditional method of forming an FRC uses the field-reversed θ-pinch technology, producing hot, high-density plasmas (see A. L. Hoffman et al., Nucl. Fusion 33, 27 (1993)). A variation on this is the translation-trapping method in which the plasma created in a theta-pinch “source” is more-or-less immediately ejected out one end into a confinement chamber. The translating plasmoid is then trapped between two strong mirrors at the ends of the chamber (see, for instance, H. Himura et al., Phys. Plasmas 2, 191 (1995)).


Significant progress has been made in the last decade developing other FRC formation methods: merging spheromaks with oppositely-directed helicities (see, e.g. Y. Ono et al., Nucl. Fusion 39, 2001 (1999)) and by driving current with rotating magnetic fields (RMF) (see, e.g. I. R. Jones, Phys. Plasmas 6, 1950 (1999)) which also provides additional stability. Recently, the collision-merging technique, proposed long ago (see, e.g. D. R. Wells, Phys. Fluids 9, 1010 (1966)) has been significantly developed further: two separate theta-pinches at opposite ends of a confinement chamber simultaneously generate two plasmoids and accelerate the plasmoids toward each other at high speed; they then collide at the center of the confinement chamber and merge to form a compound FRC. In the construction and successful operation of one of the largest FRC experiments to date, the conventional collision-merging method was shown to produce stable, long-lived, high-flux, high temperature FRCs (see, e.g. M. Binderbauer et al., Phys. Rev. Lett. 105, 045003 (2010)).


When an FRC translates into the confinement section, it induces eddy currents in any conducting structure within its vicinity (e.g. the vessel wall or conducting in-vessel components). These eddy currents influence the plasma state and decay over time, thereby contributing to a continuous evolution of the plasma and preventing any steady-state until the eddy currents have decayed to negligible magnitudes. If the conducting structures are not axisymmetric (which is generally the case), the eddy currents break the axisymmetry of the FRC. Overall, such translation-induced eddy currents are undesirable. Their initial excitation imposes constraints on the plasma shape and thereby limits the ability of conducting structures to provide passive stabilization of plasma instabilities, and their decay over time complicates plasma control by requiring continuous compensation even in the absence of plasma instabilities. Furthermore, any beneficial effects of translation-induced eddy currents can also be provided by suitable adjustments of the equilibrium magnetic field.


Translation-induced eddy currents are not the only type of eddy currents that arise during experiments. Plasma instabilities may excite eddy currents which reduce the growth rate of the instability and are thus desirable. Eddy currents will also arise in response to neutral beam current ramp-up.


Plasma lifetimes in other FRC experiments have typically been limited to values significantly lower than the resistive timescale of the conducting wall, so that time-varying eddy currents did not pose any practical problems and have not been receiving much attention.


One related technique to prevent the excitation of translation-induced eddy currents is the use of insulating axial “gaps” in the vessel to prevent the excitation of axisymmetric eddy currents. The drawback of this method is that it requires structural changes to the conducting vessel, and that eddy currents are not suppressed but axisymmetric currents are transformed into 3-D currents. This thus aggravates the detrimental effects from 3-D fields and also makes the wall unsuitable for passive stabilization of axisymmetric plasma instabilities.


Three dimensional error fields are often corrected by error field correction coils that are themselves not axisymmetric. In the best case, such coils can eliminate as many harmonics as there are coils, but they tend to introduce new errors in the remaining harmonics and need to be able to follow any time-variation of the error fields during the experiment.


Therefore, it is desirable to provide systems and methods that facilitate the reduction or elimination of undesirable eddy currents.


SUMMARY OF INVENTION

Embodiments provided herein are directed to systems and methods that facilitate the reduction in amplitude of undesirable eddy currents (wall currents), e.g., translation-induced eddy currents such as eddy currents induce by translation of FRC plasmas, while leaving beneficial eddy currents unaffected. The reduction in amplitude of undesirable eddy currents is achieved by inducing opposing currents in the same structures prior to plasma translation, for example using active coils. If both tangential and normal components of the total magnetic field on a surface separating the plasma from the conducting structures are measured, the field can be decomposed into components produced by the plasma and components produced by exterior currents (eg. equilibrium coil currents). By subtracting the known fields from exterior coils, the field due to eddy current remains. The corresponding eddy current distribution can be reconstructed from the time evolution of this field. With the eddy current distribution known, active coils are used to induce a similar distribution with an opposite sign before the plasma translates into the chamber. Calculating the necessary coil currents requires knowledge of only the geometry of the active coils and passive structures. When the plasma translates into the confinement chamber, the two eddy current distributions superimpose and cancel. The more exact the eddy current distribution is reproduced, the more complete is the cancellation.


The systems and methods described herein advantageously:

    • reduce time-varying external fields due to decaying eddy currents, which interfere with plasma control;
    • reduce symmetry-breaking effects of a non-axisymmetric wall; since both pre-induced and translation-induced eddy currents have the same 3-D structure, 3-D fields are reduced without the need for non-axisymmetric coils; and
    • enable the installation of close fitting, axisymmetric, in-vessel structures to increase passive stabilization of axisymmetric and non-axisymmetric instabilities.


Other systems, methods, features and advantages of the example embodiments will be or will become apparent to one with skill in the art upon examination of the following figures and detailed description.





BRIEF DESCRIPTION OF FIGURES

The details of the example embodiments, including structure and operation, may be gleaned in part by study of the accompanying figures, in which like reference numerals refer to like parts. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. Moreover, all illustrations are intended to convey concepts, where relative sizes, shapes and other detailed attributes may be illustrated schematically rather than literally or precisely.



FIG. 1 is a schematic of a chamber or vessel with formation tubes attached to opposing ends and axisymmetric coils positioned around the wall of the chamber for inducing eddy currents in the wall of the chamber (wall currents).



FIG. 1A is a schematic showing a control system coupled to an active coil system and a formation system.



FIG. 2 is a schematic of the chamber and formation tubes in FIG. 1 with a plasma present in the formation tube.



FIG. 3 is a schematic of the chamber and formation tubes in FIG. 1 following translation of the plasma into the chamber and showing translation-induced eddy currents formed in the wall of the chamber (translation induced wall currents).



FIG. 4 is the chamber and formation tubes in FIG. 1 prior to translation of the plasma into the chamber with pre-induced eddy currents formed in the wall of the chamber (pre-induced wall currents).



FIG. 5 is the chamber and formation tubes in FIG. 1 following translation of the plasma into the chamber and showing the pre-induced and translation-induced eddy currents in the wall of the chamber (pre-induced and translation-induced wall currents).



FIG. 6 is the chamber and formation tubes in FIG. 1 following translation of the plasma into the chamber and showing the translation-induced eddy currents in the wall of the chamber (translation induced wall currents) cancelled out by the pre-induced eddy currents in the wall of the chamber (pre-induced wall currents).



FIG. 7 is a graph showing the simulated eddy current distribution in an axisymmetric wall of the chamber (simulated wall current distribution) for three (3) cases: (1) no pre-induced, (2) pre-induced, and (3) pre-induced and adjusted vacuum field.





It should be noted that elements of similar structures or functions are generally represented by like reference numerals for illustrative purpose throughout the figures. It should also be noted that the figures are only intended to facilitate the description of the preferred embodiments.


DETAILED DESCRIPTION

Each of the additional features and teachings disclosed below can be utilized separately or in conjunction with other features and teachings to provide systems and methods that facilitate the reduction in amplitude of undesirable eddy currents (wall currents), e.g., translation-induced eddy currents, while leaving beneficial eddy currents unaffected. Representative examples of the embodiments described herein, which examples utilize many of these additional features and teachings both separately and in combination, will now be described in further detail with reference to the attached drawings. This detailed description is merely intended to teach a person of skill in the art further details for practicing preferred aspects of the present teachings and is not intended to limit the scope of the invention. Therefore, combinations of features and steps disclosed in the following detail description may not be necessary to practice the invention in the broadest sense, and are instead taught merely to particularly describe representative examples of the present teachings.


Moreover, the various features of the representative examples and the dependent claims may be combined in ways that are not specifically and explicitly enumerated in order to provide additional useful embodiments of the present teachings. In addition, it is expressly noted that all features disclosed in the description and/or the claims are intended to be disclosed separately and independently from each other for the purpose of original disclosure, as well as for the purpose of restricting the claimed subject matter independent of the compositions of the features in the embodiments and/or the claims. It is also expressly noted that all value ranges or indications of groups of entities disclose every possible intermediate value or intermediate entity for the purpose of original disclosure, as well as for the purpose of restricting the claimed subject matter.


Embodiments provided herein are directed to systems and that facilitate the reduction in amplitude of undesirable eddy currents, e.g., translation-induced eddy currents such as eddy currents induced by translating FRC plasmas, while leaving beneficial eddy currents unaffected. The eddy currents induced by translating FRC plasmas do not depend on the prior field configuration or on the presence of prior currents. Therefore, if the currents induced by the plasma translation are undesirable, they can be eliminated by creating an equal and opposite current pattern before the plasma translates.


In practice, this can be achieved, as shown in FIG. 1, with axisymmetric active coils 20 positioned around the inside or the outside of the vessel 10. Plasmas, such as, e.g., FRC plasmas, are formed in and translated toward the mid-plane of the vessel 10 from formation tubes 12 and 14 positioned on opposing ends of the vessel 10. A detailed discussion of systems and methods for forming and maintaining an FRC plasma is provided in published PCT Application No. WO 2015048092, which claims priority to U.S. Provisional Patent Application No. 61/881,874 and U.S. Provisional Patent Application No. 62/001,583, which applications are incorporated herein by reference as if set forth in full.


As shown in FIG. 1A, a control system 100 is coupled to an active coil system 200 comprising the active coils 20, power supplies and the like, and to a formation system comprising the formation tubes 12 and 14, coils or straps, power supplies and the like.


Prior to plasma translation from the formation tubes 12 and 14, the coils 20 are ramped-up and held at constant current until all eddy currents in the wall of the vessel 10 have decayed. At this point current to the coils 20 is interrupted and the plasma formation sequence is started. The interruption of current to the coils 20 will excite a specific eddy current distribution in the wall of the vessel 10 to conserve the flux through the vessel 10, until a subsequent flux injection from the translating plasma reduces the eddy currents in the wall of the vessel 10 back towards zero. Alternatively, the coils 20 may be quickly ramped-up just before the plasma translates. In this case, the quick ramp-up will produce the desired eddy current distribution in the wall of the vessel 10, and the subsequent flux injection from the translated plasma will bring the eddy currents back to zero. After translation, currents in the coils 20 are kept constant. This method may be used if the characteristic eddy current decay time of the wall 10 is sufficiently slow compared to the rate at which the coils 20 can be ramped up. Cancellation can generally be increased by optimizing the geometry of the active coils, but even with the active coil geometry prescribed, the eddy current amplitude can be reduced.


To determine the currents in the active coils that will maximize eddy current cancellation, the eddy current distribution induced by the plasma has to be measured. This can be done by measuring at least two components of the magnetic field in the region between the conducting structures and the plasma. With two components of the magnetic field known, the magnetic field can then be separated into components due to the plasma and due to external currents. This is easily seen in a cylindrical geometry, i.e., for a given mode number m and phase, the magnetic scalar potential is determined by two amplitudes, one for the term proportional to rm, and the other for the term proportional to r−m. Having two measurements of the magnetic field at the same spatial point allows solving for both coefficients, and the field from the plasma is trivially identified with the term proportional to rm. In more complicated geometries the mathematics are not as straightforward but the same procedure can be used. With the time evolution of both the internal and external magnetic field known, the current distribution in the conducting structures can be computed by least-squares fitting to a finite-element circuit model.



FIGS. 2-6 illustrate the basic idea of reducing translation-induced eddy currents. Plasma currents (white filled), plasma induced wall currents (gray filled), and pre-induced wall currents (cross-hatched filled) are shown in the figures in two stages, i.e., 1) prior to translation and 2) after translation. In FIGS. 2 and 3, no wall currents have been pre-induced in the wall of the vessel 10, so the net current in the wall is a non-zero value after translation of the plasma from the formation tubes 12 and 14. In FIGS. 4-6, some currents have been pre-induced in the wall of the vessel 10. After translation of the plasma from the formation tubes 12 and 14, the net current in the wall becomes zero.


Application of the proposed technique has been simulated using LamyRidge, a 2-fluid simulation code to evaluate its effects on plasma formation and translation. FIG. 7 shows the eddy current distribution in an axisymmetric wall two hundred microseconds (200 ms) after formation for three different cases:

    • 1) In case 1 custom character, no eddy current compensation was utilized, resulting in a plasma with separatrix radius 39 cm and elongation 2.5.
    • 2) In case 2 custom character an (exactly) opposing current pattern was put on the wall prior to start of the formation. As expected, the amplitude of the eddy currents at the end of the simulation is reduced. The currents do not cancel exactly, because the presence of the pre-induced currents results in an expansion of the plasma, so that it reaches a radius of 46 cm with an elongation of 2.0.
    • 3) In Case 3 custom character in addition to pre-inducing eddy currents in the chamber wall, the currents in the confinement coils are adjusted to compensate for the suppressed eddy currents. In other words, the field produced by the confinement coils in case 3 at t=0 is now equal to the field produced by both confinement coils and eddy currents in case 1 at t=200 us. This results in a plasma that is very similar to case 1 (radius 38 cm, elongation 2.5), but the eddy currents have been reduced by a factor of 10. Subsequent evolution of this plasma is therefore much less affected by wall eddy currents and thus easier to control and predict. Furthermore, by adjusting the pre-induced wall currents together with the confinement coils, the plasma separatrix radius can be directly controlled.


      Other Advantages


To stabilize FRC position or shape, axisymmetric, conducting in-vessel passive structures may be used. If eddy currents are pre-induced in the in-vessel passive structures in a manner as described above, the in-vessel passive structures can be installed without affecting initial plasma shape and configuration. If, on the other hand, no currents are pre-induced, installation of the in-vessel passive structures will decrease the FRC radius and thus reduce the coupling between in-vessel passive structures and plasma to approximate the same coupling strength that was previously between the wall of the vessel and the plasma, neglecting much of the advantage of installing additional components in the vessel


A similar issue applies to control coils. Where ex-vessel coils have insufficient plasma coupling to stabilize plasma instabilities and in-vessel coils are used, the in-vessel coils need to be protected from the plasma typically with an additional internal wall. If eddy currents in this in-vessel coil wall are not eliminated, they will reduce the plasma radius and the intended increase in coil-plasma coupling will be reduced. Therefore, eliminating eddy currents increases the coupling between coils and plasma, and thus reduces both current and voltage requirements for control coils.


Due to the 3-D shape of the vessel, any induced wall currents will break axisymmetry and potentially reduce confinement, excite instabilities, or otherwise reduce performance. Error field correction coils can be used to reduce a fixed number of specific harmonics, but are non-axisymmetric themselves and thus further amplify other sideband harmonics. In contrast, elimination of the eddy currents as described above requires only axisymmetric coils, results in less sideband harmonics, and does not require any currents in the coils after the plasma has formed.


In summary, the proposed systems and methods provided herein increase the chance of stabilizing plasma instabilities; increase the efficiency of plasma control systems by improving the coupling to the wall, reduces the amplitude of symmetry breaking 3-D fields, and lowers the complexity of the real-time systems. Up to some degree, all of these advantages can also be realized with very little cost by re-using existing coil systems. Best results can be achieved by taking eddy current elimination into account for coil placement and design.


The example embodiments provided herein advantageously reduces time-varying external fields due to decaying eddy currents, which interfere with plasma control; reduces symmetry-breaking effects of a non-axisymmetric wall (since both pre-induced and translation-induced eddy currents have the same 3-D structure, 3-D fields are reduced without the need for non-axisymmetric coils) and enables the installation of close fitting, axisymmetric, in-vessel structures to increase passive stabilization of axisymmetric and non-axisymmetric instabilities.


The example embodiments provided herein, however, are merely intended as illustrative examples and not to be limiting in any way.


In the foregoing specification, the invention has been described with reference to specific embodiments thereof. It will, however, be evident that various modifications and changes may be made thereto without departing from the broader spirit and scope of the invention. For example, the reader is to understand that the specific ordering and combination of process actions shown in the process flow diagrams described herein is merely illustrative, unless otherwise stated, and the invention can be performed using different or additional process actions, or a different combination or ordering of process actions. As another example, each feature of one embodiment can be mixed and matched with other features shown in other embodiments. Features and processes known to those of ordinary skill may similarly be incorporated as desired. Additionally and obviously, features may be added or subtracted as desired. Accordingly, the invention is not to be restricted except in light of the attached claims and their equivalents.

Claims
  • 1. A method for reducing undesired eddy currents induced in a conducting structure, the method comprising the steps of: inducing a first set of eddy currents in a conducting structure, andtranslating a plasma into the conducting structure, wherein the plasma translating into the plasma confinement vessel to inducing a second set of eddy currents in the conducting structure, wherein the first set of eddy currents being induced prior to the second set of eddy currents and having a distribution equal to and opposite in sign to the distribution of the second set of eddy currents to substantial cancel the second set of eddy currents upon inducement of the second set of eddy currents in the conducting structure.
  • 2. The method of claim 1 wherein the conducting structure is a wall of a plasma confinement vessel.
  • 3. The method of claim 1 wherein the step of inducing eddy currents in a conducting structure includes the steps of ramping up and holding coils about the conducting structure at a constant current until all eddy currents have decayed in the conducting structure, andinterrupting current to the coils to allow the first set of eddy currents to excite in the conducting structures conserving the magnetic flux through the structures.
  • 4. The method of claim 1 wherein the translating plasma injects a flux into the conducting structure that induces the second set of eddy currents in the conducting structure reducing the amplitude of eddy currents in the conducting structure back towards zero.
  • 5. The method of claim 3 wherein the translating plasma injects a flux into the conducting structure that induces the second set of eddy currents in the conducting structure reducing the amplitude of eddy currents in the wall of the vessel back towards zero.
  • 6. The method of claim 1 wherein the step of inducing a first set of eddy currents in a conducting structure includes the steps of ramping up and holding coils about the conducting structure at a constant current to produce the first set of eddy currents in the conducting structure, andwherein the translating plasma injects a flux into the conducting structure that induces the second set of eddy currents in the conducting structure reducing the amplitude of eddy currents in the conducting structure back towards zero.
  • 7. A system for reducing undesired eddy currents induced in a vessel wall, the system comprising: a vessel having a wall and an interior,a formation section attached to an end of the vessel,a plurality coils positioned around the vessel, anda control system coupled to the plurality of coils and configured to induce a first set of eddy currents in the wall of the vessel prior to a second set of eddy currents being induced in the wall of the vessel, wherein the first set of eddy currents having a distribution equal to and opposite in sign to the distribution of the second set of eddy currents to substantial cancel the second set of eddy currents upon inducement of the second set of eddy currents in the wall of the chamber, wherein the control system is further configured to translate a plasma from the formation section into the interior of the vessel, wherein the translating plasma induces the second set of eddy currents in the wall of the vessel.
  • 8. The system of claim 7 wherein the control system is further configured to ramp up and hold the plurality of coils at a constant current until all eddy currents in the wall of the vessel have decayed, and then interrupt the current to the plurality of coils to allow the first set of eddy currents to excite in the wall of the vessel conserving the flux through the vessel.
  • 9. The system of claim 8 wherein the translating plasma injects a flux into the wall of the vessel that induces the second set of eddy currents in the wall of the vessel reducing the amplitude of eddy currents in the wall of the vessel back towards zero.
  • 10. The system of claim 7 wherein the control system is further configured to ramp up and hold the plurality of coils at a constant current to produce the first set of eddy currents in the conducting structure.
  • 11. The system of claim 10 wherein the translating plasma injects a flux into the wall of the vessel that induces the second set of eddy currents in the wall of the vessel reducing the amplitude of eddy currents in the wall of the vessel back towards zero.
  • 12. A method for reducing undesired eddy currents induced in a wall of a vessel, the method comprising the steps of: inducing a first set of eddy currents in a wall of a vessel having a wall and an interior prior to inducing a second set of eddy currents in the wall of the vessel, andtranslating a plasma into the vessel, wherein the plasma translating into the plasma confinement vessel inducing a second set of eddy currents in the wall of the vessel, wherein the first set of eddy currents having a distribution equal to and opposite in sign to the distribution of the second set of eddy currents to substantial cancel the second set of eddy currents upon inducement of the second set of eddy currents in the wall of the vessel.
  • 13. The method of claim 12 wherein the step of inducing eddy currents in the wall of the vessel includes the steps of ramping up and holding a plurality of coils positioned about the wall of the vessel at a constant current until all eddy currents have decayed in the wall of the vessel, andinterrupting current to the plurality of coils to allow the first set of eddy currents to excite in the wall of the vessel conserving the magnetic flux through the wall of the vessel.
  • 14. The method of claim 12 wherein the translating plasma injects a flux into the wall of the vessels that induces the second set of eddy currents in the wall of the vessel reducing the amplitude of eddy currents in the wall of the vessel back towards zero.
  • 15. The method of claim 13 wherein the translating plasma injects a flux into the wall of the vessels that induces the second set of eddy currents in the wall of the vessel reducing the amplitude of eddy currents in the wall of the vessel back towards zero.
  • 16. The method of claim 12 wherein the plasma is translated from opposing formation sections attached to opposite ends of the vessel.
  • 17. The method of claim 16, further comprising the step of forming an FRC plasma in the opposing formation sections and wherein the step of translating a plasma into the vessel comprises translating the FRC plasma into the vessel.
  • 18. The method of claim 12 wherein the step of inducing eddy currents in the wall of the vessel includes the steps of ramping up and holding a plurality of coils positioned about the wall of the vessel at a constant current to produce the first set of eddy currents in the wall of the vessel, andwherein the translating plasma injects a flux into the wall of the vessel that induces the second set of eddy currents in the wall of the vessel reducing the amplitude of eddy currents in the wall of the vessel back towards zero.
  • 19. The method of claim 18 wherein the plasma is translated from opposing formation sections attached to opposite ends of the vessel.
  • 20. The method of claim 19, further comprising the step of forming a field reversed configuration (FRC) plasma in the opposing formation sections and wherein the step of translating a plasma into the vessel comprises translating the FRC plasma into the vessel.
CROSS-REFERENCE TO RELATED APPLICATIONS

The subject application is a continuation of PCT Patent Application No. PCT/US16/31539, filed May 9, 2016, which claims priority to U.S. Provisional Patent Application No. 62/160,421, filed on May 12, 2015, both of which are incorporated by reference herein in their entirety for all purposes.

US Referenced Citations (178)
Number Name Date Kind
3015618 Stix Jan 1962 A
3036963 Christofilos May 1962 A
3052617 Post Sep 1962 A
3071525 Christofilos Jan 1963 A
3120470 Imhoff et al. Feb 1964 A
3132996 Baker et al. May 1964 A
3170841 Post Feb 1965 A
3182213 Rosa May 1965 A
3258402 Farnsworth Jun 1966 A
3386883 Farnsworth Jun 1968 A
3527977 Ruark Sep 1970 A
3530036 Hirsch Sep 1970 A
3530497 Hirsch et al. Sep 1970 A
3577317 Woods May 1971 A
3621310 Takeuchi et al. Nov 1971 A
3663362 Stix May 1972 A
3664921 Christofilos May 1972 A
3668065 Moir Jun 1972 A
3859164 Nowak Jan 1975 A
4010396 Ress et al. Mar 1977 A
4054846 Smith et al. Oct 1977 A
4057462 Jassby et al. Nov 1977 A
4065351 Jassby et al. Dec 1977 A
4098643 Brown Jul 1978 A
4166760 Fowler et al. Sep 1979 A
4182650 Fischer Jan 1980 A
4189346 Jarnagin Feb 1980 A
4202725 Jarnagin May 1980 A
4233537 Limpaecher Nov 1980 A
4246067 Linlor Jan 1981 A
4267488 Wells May 1981 A
4274919 Jensen et al. Jun 1981 A
4303467 Scornavacca et al. Dec 1981 A
4314879 Hartman et al. Feb 1982 A
4317057 Bazarov et al. Feb 1982 A
4347621 Dow Aug 1982 A
4350927 Maschke Sep 1982 A
4371808 Urano et al. Feb 1983 A
4390494 Salisbury Jun 1983 A
4397810 Salisbury Aug 1983 A
4416845 Salisbury Nov 1983 A
4434130 Salisbury Feb 1984 A
4483737 Mantei Nov 1984 A
4543231 Ohkawa Sep 1985 A
4543465 Sakudo et al. Sep 1985 A
4548782 Manheimer et al. Oct 1985 A
4560528 Ohkawa Dec 1985 A
4584160 Kageyama Apr 1986 A
4584473 Hashimoto et al. Apr 1986 A
4601871 Turner Jul 1986 A
4615755 Tracy et al. Oct 1986 A
4618470 Salisbury Oct 1986 A
4630939 Mayes Dec 1986 A
4639348 Jarnagin Jan 1987 A
4650631 Knorr Mar 1987 A
4687616 Moeller Aug 1987 A
4826646 Bussard May 1989 A
4853173 Stenbacka Aug 1989 A
4894199 Rostoker Jan 1990 A
4904441 Sorensen et al. Feb 1990 A
4922800 Hoffman May 1990 A
5015432 Koloc May 1991 A
5041760 Koloc Aug 1991 A
5122662 Chen et al. Jun 1992 A
5160694 Steudtner Nov 1992 A
5160695 Bussard Nov 1992 A
5206516 Keller et al. Apr 1993 A
5207760 Dailey et al. May 1993 A
5339336 Sudan Aug 1994 A
5355399 Golovanivsky et al. Oct 1994 A
5420425 Bier et al. May 1995 A
5422481 Louvet Jun 1995 A
5451877 Weissenberger Sep 1995 A
5473165 Stinnett et al. Dec 1995 A
5483077 Glavish Jan 1996 A
5502354 Correa et al. Mar 1996 A
5537005 Goebel et al. Jul 1996 A
5557172 Tanaka Sep 1996 A
5656519 Mogami Aug 1997 A
5656819 Greenly Aug 1997 A
5677597 Tanaka Oct 1997 A
5747800 Yano et al. May 1998 A
5764715 Maenchen et al. Jun 1998 A
5811201 Skowronski Sep 1998 A
5846329 Hori et al. Dec 1998 A
5848110 Maenchen et al. Dec 1998 A
5923716 Meacham Jul 1999 A
6000360 Koshimizu Dec 1999 A
6084356 Seki et al. Jul 2000 A
6245190 Masuda et al. Jun 2001 B1
6248251 Sill Jun 2001 B1
6255648 Littlejohn et al. Jul 2001 B1
6271529 Farley et al. Aug 2001 B1
6322706 Ohkawa Nov 2001 B1
6335535 Miyake et al. Jan 2002 B1
6345537 Salamitou Feb 2002 B1
6376990 Allen Apr 2002 B1
6390019 Grimbergen et al. May 2002 B1
6396213 Koloc May 2002 B1
6408052 McGeoch Jun 2002 B1
6452168 McLuckey et al. Sep 2002 B1
6466017 Ganin Oct 2002 B1
6477216 Koloc Nov 2002 B2
6488807 Collins et al. Dec 2002 B1
6593539 Miley et al. Jul 2003 B1
6593570 Li et al. Jul 2003 B2
6611106 Monkhorst et al. Aug 2003 B2
6628740 Monkhorst et al. Sep 2003 B2
6632324 Chan Oct 2003 B2
6664740 Rostoker et al. Dec 2003 B2
6712927 Grimbergen et al. Mar 2004 B1
6755086 Salamitou et al. Jun 2004 B2
6850011 Monkhorst et al. Feb 2005 B2
6852942 Monkhorst et al. Feb 2005 B2
6888907 Monkhorst et al. May 2005 B2
6891911 Rostoker et al. May 2005 B2
6894446 Monkhorst et al. May 2005 B2
6903550 Uetake Jun 2005 B2
6995515 Rostoker et al. Feb 2006 B2
7002148 Monkhorst et al. Feb 2006 B2
7002343 Weissenberger Feb 2006 B2
7015646 Rostoker et al. Mar 2006 B2
7026763 Rostoker et al. Apr 2006 B2
7115887 Hassanein et al. Oct 2006 B1
7119491 Rostoker et al. Oct 2006 B2
7126284 Rostoker et al. Oct 2006 B2
7129656 Rostoker et al. Oct 2006 B2
7180242 Rostoker et al. Feb 2007 B2
7232985 Monkhorst et al. Jun 2007 B2
7391160 Monkhorst et al. Jun 2008 B2
7439678 Rostoker et al. Oct 2008 B2
7459654 Monkhorst et al. Dec 2008 B2
7477718 Rostoker et al. Jan 2009 B2
7569995 Rostoker et al. Aug 2009 B2
7613271 Rostoker et al. Nov 2009 B2
7719199 Monkhorst May 2010 B2
7786675 Yakovlev Aug 2010 B2
7816870 Yakovlev Oct 2010 B2
8031824 Bystriskii et al. Oct 2011 B2
8461762 Rostoker et al. Jun 2013 B2
8836248 Verheijen Sep 2014 B2
8854037 Feiweier Oct 2014 B2
9072156 Caporaso Jun 2015 B2
9157973 Yamanaka Oct 2015 B2
9265137 Rostoker et al. Feb 2016 B2
9370086 Rostoker et al. Jun 2016 B2
9386676 Rostoker et al. Jul 2016 B2
9564248 Bystriskii Feb 2017 B2
9591740 Belchenko et al. Mar 2017 B2
9672943 Rostoker et al. Jun 2017 B2
9924587 Belchenko Mar 2018 B2
9997261 Tuszewski Jun 2018 B2
10002680 Laberge Jun 2018 B2
10049774 Tuszewski Aug 2018 B2
20010006093 Tabuchi et al. Jul 2001 A1
20020101949 Nordberg Aug 2002 A1
20030197129 Murrell et al. Oct 2003 A1
20030230240 Rostoker et al. Dec 2003 A1
20030230241 Rostoker et al. Dec 2003 A1
20040046554 Carlini Mar 2004 A1
20040213368 Rostoker et al. Oct 2004 A1
20040251996 Nordberg Dec 2004 A1
20050249324 Meacham Nov 2005 A1
20060198485 Binderbauer Sep 2006 A1
20060202687 Wang Sep 2006 A1
20080226011 Barnes Sep 2008 A1
20100020913 Mozgovoy Jan 2010 A1
20110142185 Woodruff Jun 2011 A1
20110293056 Slough Dec 2011 A1
20120217966 Feiweier Aug 2012 A1
20140084925 Nieminen et al. Mar 2014 A1
20150187443 Tuszewski Jul 2015 A1
20150216028 Laberge et al. Jul 2015 A1
20160098058 Morehouse et al. Apr 2016 A1
20160276044 Tuszewski et al. Sep 2016 A1
20170135194 Belchenko et al. May 2017 A1
20170236599 Bystriskii et al. Aug 2017 A1
20170359886 Binderbauer et al. Dec 2017 A1
Foreign Referenced Citations (7)
Number Date Country
101320599 Dec 2008 CN
104051028 Sep 2014 CN
2389048 Nov 2011 EP
2 270 733 Dec 1975 FR
1387098 Mar 1975 GB
2056649 Mar 1996 RU
WO 2014114986 Jul 2014 WO
Non-Patent Literature Citations (100)
Entry
TW, 105114777 Search Report, dated Nov. 6, 2017.
WO, PCT/US2016/031539 ISR and Written Opinion, dated Aug. 18, 2016.
Anderson, M., et al., “Plasma and Ion Beam Injection into an FRC”, Plasma Physics Reports, 2005, vol. 31, No. 10, pp. 809-817.
Arsenin, V.V., et al., “Suppression of plasma instabilities by the feedback method”, Soviet Physics Uspekhi, 1977, vol. 20, No. 9, pp. 736-745.
Artsimovich, L.A., “Controlled Thermonuclear Reactions”, English Edition, 1964, Gordon and Breach, Science Publishers, Inc., New York, pp. 1-9.
Asai, T., et al., “End Loss Measurement of Neutral-Beam-Injected Field-Reversed Configuration Plasma”, J. Plasma Fusion Res. Series, vol. 5, 2002, pp. 220-224.
Avanzini, P.G., “Feasibility of Fusion Power Generation by Accelerated Ion Beams”, ICENES, Jun. 30-Jul. 4, 1986, Geneva, Italy, pp. 305-309.
Becker, H.W., et al., “Low-Energy Cross Sections for 11B(p,3α)”, Z. Physics A—Atomic Nuclei, 1987, vol. 217, No. 3, pp. 341-355.
Binderbauer, M.W., et al., “Turbulent transport in magnetic confinement: how to avoid it”, Journal of Plasma Physics, 1996, vol. 56, No. 3, pp. 451-465.
Binderbauer, M.W., et al., “Dynamic Formation of a Hot Field Reversed Configuration with Improved Confinement by Supersonic Merging of Two Colliding High-β Compact Toroids”, Phys. Rev. Lett., 2010, vol. 105, No. 4, pp. 045003-1-045003-4.
Bohm, D., “Quantum Theory”, 1951, Dover Publications, Inc., New York, Chapter 12—Applications to Simple Systems, The Classical Limit and the WKB Approximation, pp. 277-283.
Bystritskii, V., et al., “Generation and Transport of a Low-Energy Intense Ion Beam”, IEEE Transactions on Plasma Science, 2004, vol. 32, No. 5, pp. 1986-1992.
Bystritskii, V., et al., “Study of Dense FRCs Formation and Their Transport With Multistage Compression”, IEEE 2013 IEEE Pulsed Power and Plasma Science Conference (PPPS 2013)—San Francisco, CA, USA, Jun. 2013, 1 page.
Carlson, A., “Re: Boron/Proton colliding beam reactor?”, 1997, retrieved from http://groups.google.com/groups?q=rostok . . . opuo.fsr%40s4awc.aug.ipp-garching.mpg.de, pp. 1-3.
Carlson, A., “Fundamental Limitations on Plasma Fusion Systems Not in Thermodynamic Equilibrium”, 1997, retrieved from http://www.ipp.mpg.de/˜Arthur.Carlson/rider.html, pp. 1-3.
Carlson, A., “Annotated Bibliography of p-B11 Fusion”, 1998, retrieved from http://www.igg.mpg.de/˜Arthur.carlson/p-B11-bib.html, pp. 1-4.
Carlson, A., “Home p. of Dr. A. Carlson”, 2000, retrieved from http://www/rzg/mpg.de/˜awc/home.html, pp. 1-2.
Carlson, A., “Re: Lithium Fission—why not?,” 2000, retrieved from http://groups.google.com/groups?q=rostok . . . v35u.fsi%40suawc.aug.ipp-garching.mpg.de, pp. 1-2.
Chao, A.W., et al., Handbook of Accelerator Physics and Engineering, 2nd Printing, 1998, World Scientific, Chapter 2, pp. 53, 119-120.
Cohen, S.A., et al., “Formation of Collisionless High-β Plasmas by Odd-Parity Rotating Magnetic Fields”, Physical Review Letters, 2007, vol. 98, pp. 125002-1-145002-4.
Cohen, S.A., et al., “RMFo-Formed Collisionless High-β Plasmas: Yesterday, Today and Tomorrow”, AIP Conference Proceedings, vol. 1154, 2009, pp. 165-166.
Cox, Jr., L/T., et al., “Thermonuclear Reaction Listing With Cross-Section Data for Four Advanced Reactions”, Fusion Technology, 1990, vol. 18, No. 2, pp. 325-339.
Davis, H.A., et al., “Generation of Field-Reversing E Layers with Millisecond Lifetimes”, Physical Review Letters, 1976, vol. 37, No. 9, pp. 542-545.
Dawson, J.M., “Advanced Fuels for CTR”, Four Workshops in Alternate Concepts in Controlled Fusion, EPRI ER-429-SR, Special Report, Part B: Extended Summaries, 1977, pp. 143-147.
Dawson, J.M., “Alternate Concepts in Controlled Fusion”, EPRI ER-429-SR, Special Report, Part C: CTR Using the p-11 B Reaction, 1977, pp. ii-30.
Dobrott, D., “Alternate Fuels in Fusion Reactors”, Nuclear Technology/Fusion, 1983, vol. 4, pp. 339-347.
Dolan, T.J, “Fusion Research”, 1982, vol. II—Experiments, Pergamon Press, New York, pp. 277-309.
Feldbacher, R., et al., “Basic Cross Section Data for Aneutronic Reactor”, Nuclear Instruments and Methods in Physics Research A271, 1988, pp. 55-64.
Finn, J.M., et al., “Field-Reversed Configurations With a Component of Energetic Particles”, Nuclear Fusion, 1982, vol. 22, No. 11, pp. 1443-1518.
Garrido Alzar, C. L., et al., “Compensation of eddy-current-induced magnetic field transients in a MOT”, 2007, retrieved from http://arxiv.org/pdf/physics/0701251.pdf.
Goldston, R.J., et al., “Fusion Alternatives”, Science, 1997, vol. 278, No. 5346, pp. 2031-2037.
Gota, H., et al., A Well-Confined Field-Reversed Configuration Plasma Formed by Dynamic Merging of Two Colliding Compact Toroids in C-2, ICC and CT Workshops, Aug. 16, 2011, retrieved from http://www.iccworkshops.org/icc2011/uploads/241/icc2011_gota_talk_8_16_11.pdf, pp. 1-19.
Guo, H. Y., et al., “Flux Conversion and Evidence or Relaxation in a High-β Plasma Formed by High-Speed Injection into a Mirror Confinement Structure”, Phys. Rev. Lett., 2004, vol. 92, No. 24, pp. 245001-1-245001-4.
Heidbrink, W.W., et al., “Comparison of Experimental and Theoretical Fast Ion Slowing-Down Times in DIII-D”, Nuclear Fusion, 1988, vol. 28, No. 1, pp. 1897-1901.
Heidbrink, W.W., “Measurements of classical deceleration of beam ions in the DIII-D tokamak”, Phys. Fluids B. 1990, vol. 2, No. 1, pp. 4-5.
Heidbrink, W.W., et al., “The diffusion of fast ions in Ohmic TFTR discharges”, Phys. Fluids B, 1991, vol. 3, No. 11, pp. 3167-3170.
Heidbrink, W.W., et al., “The Behaviour of Fast Ions in Tokamak Experiments”, Nuclear Fusion, 1994, vol. 34, No. 4, pp. 535-618.
Himura, H., et al., “Rethermalization of a field-reversed configuration plasma in translation experiments”, Phys. Plasmas, 1995, vol. 2, No. 1, pp. 191-197.
Hoffman, A.L., et al., “Field Reversed Configuration Lifetime Scaling Based on Measurements From the Large s Experiment”, Nucl. Fusion, 1993, vol. 33, No. 1, pp. 27-38.
Iwanenko, D., et al., “On the Maximal Energy Attainable in a Betatron”, Physical Review, 1944, vol. 65, Nos. 11 and 12, p. 343.
Jeffries, C.D., “A Direct Determination of the Magnetic Moment of the Protons in Units of the Nuclear Magneton”, Physical Review, 1951, vol. 81, No. 6, pp. 1040-1055.
Jones, I. R., “A review of rotating magnetic field current drive and the operation of the rotamak as a field-reversed configuration (Rotamak-FRC) and a spherical tokamak (Rotamak-ST)”, Physics of Plasmas, 1999, vol. 6, No. 5, pp. 1950-1957.
Kalinowsky, H., “Deceleration of antiprotons from MeV to keV energies”, Hyperfine Interactions, 1993, vol. 76, pp. 73-80.
Lampe, M., et al., “Comments on the Colliding Beam Fusion Reactor Proposed by Rostoker, Binderbauer and Monkhorst for Use with the p-11B Fusion Reaction”, Naval Research Lab., Plasma Physics Division, Oct. 30, 1998, pp. 1-37.
“Laval nozzle”, 1992, Academic Press Dictionary of Science and Technology, retrieved from http://www.credoreference.com/entry/3122475/.
Lawson, J.D., “Some Criteria for a Power Producing Thermonuclear Reactor”, Proc. Phys. Soc. B70, 1957, pp. 6-10.
Lifschitz, A.F., et al., “Calculations of tangential neutral beam injection current drive efficiency for present moderate flux FRCs”, Nucl. Fusion, 2004, vol. 44, pp. 1015-1026.
Majeski, R., et al., “Enhanced Energy Confinement and Performance in a Low-Recycling Tokamak”, Physical Review Letters, 2006, vol. 97, pp. 075002-1-075002-4.
Miley, G.H., et al., “A possible route to small, flexible fusion units”, Energy, vol. 4, pp. 163-170.
Miley, G.H., et al., “On design and development issues for the FRC and related alternate confinement concepts”, Fusion Engineering and Design, 2000, vol. 48, pp. 327-337.
Naitou, H., et al., “Kinetic Effects on the Convective Plasma Diffusion and the Heat Transport”, Journal of the Physical Society of Japan, 1979, vol. 46, No. 1, pp. 258-264.
Nevins, W.M., “Feasibility of a Colliding Beam Fusion Reactor”, Science, 1998, vol. 281. No. 5375, p. 307.
Okada, S., et al., “Experiments on additional heating of FRC plasmas”, Nucl. Fusion, 2001, vol. 41, No. 5, pp. 625-629.
Ono, Y., et al., “New relaxation of merging spheromaks to a field reversed configuration”, Nucl. Fusion, 1999, vol. 39, No. 11Y, pp. 2001-2008.
Phelps, D.A., et al., “Observations of the stable equilibrium and classical diffusion of field reversing relativistic electron coils”, The Physics of Fluids, 1974, vol. 17, No. 12, pp. 2226-2235.
“Summary”, Plasma Science—Advancing Knowledge in the National Interest, National Research Counsel of the National Academies, 2007, The National Academies Press, Washington, D.C., pp. 1-5.
Post, R.F., “Nuclear Fusion”, McGraw-Hill Encyclopedia of Science & Technology, 6th Edition, 1987, pp. 142-153.
Rider, T.H., “A general critique of inertial-electrostatic confinement fusion systems”, Physics Plasmas, 1995, vol. 2, No. 6, pp. 1853-1872.
Rider, T.H., “Fundamental limitations on plasma fusion systems not in thermodynamic equilibrium”, Physics Plasmas, 1997, vol. 4, No. 4, pp. 1039-1046.
Robinson, Jr., C.A., “Army Pushes New Weapons Effort”, Aviation Week & Space Technology, 1978, vol. 109, pp. 42-53.
Rosenbluth, M.N., et al., “Fokker-Planck Equation for an Inverse-Square Force”, The Physical Review, 1957, vol. 107, No. 1, pp. 1-6.
Rostoker, N., “Large Orbit Magnetic Confinement Systems for Advanced Fusion Fuels”, Final Technical Report, U.S. Dept. of Commerce, National Technical Information Service, Apr. 1, 1990-Feb. 29, 1992, pp. i-80.
Rostoker, N., et al., “Self-Colliding Systems for Aneutronic Fusion”, Comments on Plasma Physics and Controlled Fusion, 1992, vol. 15, No. 2, pp. 105-120.
Rostoker, N., et al., “Large Orbit Confinement for Aneutronic Systems”, Non-Linear and Relativistic Effects in Plasmids, editor V. Stefan, 1992, American Institute of Physics, New York, pp. 116-135.
Rostoker, N., et al., “Magnetic Fusion with High Energy Self-Colliding Ion Beams”, Physical Review Letters, 1993, vol. 70, No. 12, pp. 1818-1821.
Rostoker, N., et al., “Self-Colliding Beams as an Alternative Fusion System”, 10th International Conference on High Power Particle Beams, San Diego, CA, Jun. 20-24, 1994, pp. 195-201.
Rostoker, N., et al., “Classical Scattering in a High Beta Self-Collider/FRC”, AIP Conference Proceedings 311, 1994, Physics of High Energy Particles in Toroidal Systems, Irvine, CA 1993, pp. 168-185.
Rostoker, N., et al., “Self-Colliding Beams as an Alternative Fusion System for D-He3 Reactors”, Current Trends in International Fusion Research, edited by Panarella, Plenum Press, New York, 1997, Chapter 4, pp. 33-41.
Rostoker, N., et al., “Alternative Fusion Concepts”, Current Trends in International Fusion Research, edited by Panarella, Plenum Press, New York, 1997, Chapter 32, pp. 489-495.
Rostoker, N., et al., “Fusion Reactors Based on Colliding Beams in a Field Reversed Configuration Plasma”, Comments on Plasma Physics and Controlled Fusion, 1997, vol. 18, No. 1, pp. 11-23.
Rostoker, N., “Colliding Beam Fusion Reactor”, 12th International Conference on High-Power Particle Beams, Proceedings—vol. 1, Jun. 7-12, 1997, Haifa, Israel.
Rostoker, N., et al., “Colliding Beam Fusion Reactor”, Science, 1997, vol. 278, No. 5342, pp. 1419-1422.
Rostoker, N., “Advanced Fusion Energy and Future Energy Mix Scenarios”, Abstracts with Programs, 1999 Annual Meeting & Exposition, Oct. 25-28, 1999, Denver, CO.
Ruggiero, A.G., “Proton-Boron Colliding Beams for Nuclear Fusion”, Proceedings of ICONE 8, 8th International Conference on Nuclear Engineering, Apr. 2-6, 2000, Baltimore, MD, pp. 1-11.
Shishlov, A.V., et al., “Long time implosion experiments with double gas puffs”, Physics of Plasmas, 2000, vol. 7, No. 4, pp. 1252-1262.
Smirnov, A., et al., “Neutral Beam Dump Utilizing Cathodic Arc Titanium Evaporation”, Fusion Science and Technology, vol. 59, No. 1, 2010, pp. 271-273.
Smirnov, A., et al., “Neutral beam dump with cathodic arc titanium gettering”, Rev. Sci. Instr., 2011, vol. 82, pp. 033509-1-033509-6.
Song, Y., et al., “Electron trapping and acceleration in a modified elongated betatron”, Phys. Fluids B, 1992, vol. 4, No. 11, pp. 3771-3780.
Speth, E., et al., “Overview of RF Source Development at IPP”, CCNB-Meeting at Padua, Jun. 5-6, 2003, pp. 1-29.
Steinhauer, L.C., et al., “FRC 2001: A White Paper on FRC Development in the Next Five Years”, Fusion Technology, 1996, vol. 30, No. 1, pp. 116-127.
Tandem Energy Corporation Presentation, Dec. 12, 1997, Washington, D.C., pp. 1-47.
Tomita, Y., et al., “Direct Energy Conversion System for D-3He Fusion”, 7th International Conference on Emerging Nuclear Energy Systems, ICENES '93, 1994, pp. 522.526.
Tuszewski, M., “Field Reversed Configurations”, Nuclear Fusion, 1988, vol. 28, No. 11, pp. 2033-2092.
Tuszewski, M., “Status of the Field-Reversed Configuration as an Alternate Confinement Concept”, Fusion Technology, 1989, vol. 15, No. 11, pp. 1148-1153.
Vinyar, I., et al., “Pellett Injectors Developed at PELIN for JET, TAE, and HL-2A”, Fusion Engineering and Design, 2011, vol. 86, pp. 2208-2211.
Ware, A.A., et al., “Electrostatic Plugging of Open-Ended Magnetic Containment Systems”, Nuclear Fusion, 1969, vol. 9, No. 4, pp. 353-361.
Weaver, T., et al., “Exotic CTR Fuels for Direct Conversion-Utilizing Fusion Reactors”, Talk before the AEC CTR Staff, Mar. 16, 1973, AEC/Germantown.
Weaver, T., et al., “Fusion Microexplosions, Exotic Fusion Fuels, Direct Conversion: Advanced Technology Options for CTR”, Annual Meeting of the Committee on Advance Development and the Fusion Task Force of the Edison Electric Institute, Apr. 27, 1973, Los Alamos Scientific Laboratory, CA.
Weaver, T., et al., “Exotic CTR Fuels: Non-Thermal Effects and Laser Fusion Applications”, 1973 Annual Meeting of the American Physical Society Division of Plasma Physics, Oct. 31-Nov. 3, 1973, Philadelphia, PA, pp. 1-12.
“Welcome to Colliding Beam Fusion”, retrieved from http://fusion.ps.uci.edu/beam/introb.html on Oct. 11, 2000, pp. 1-3.
Wells, D. R., “Injection and Trapping of Plasma Vortex Structures”, Phys. Fluids, 1966, vol. 9, No. 5, pp. 1010-1021.
Wessel, F.J., et al., “D-T Beam Fusion Reactor”, Journal of Fusion Energy, 1998, vol. 17, No. 3, pp. 209-211.
Wessel, F.J., et al., “Colliding Beam Fusion Reactor Space Propulsion System”, AIP Conference Proceedings 504, 2000, pp. 1425-1430.
“A White Paper on FRC Development”, Apr. 1998, retrieved from http://depts.washington.edu/rppl/programs/wpr98.pdf, pp. 1-26.
Wong, H.V., et al., “Stability of annular equilibrium of energetic large orbit ion beam”, Phys. Fluids B, 1991, vol. 3, No. 11, pp. 2973-2986.
Zweben, S.J., et al., “Radial Diffusion Coefficient for Counter-Passing MeV Ions in the TFTR Tokamak”, Nuclear Fusion, 1991, vol. 31, No. 12, pp. 2219-2245.
SG, 11201708790V Written Opinion, dated Oct. 31, 2018.
EP, 16793344.9 Supplementary Search Report, dated Nov. 12, 2018.
Chapman, B. E., et al., “Observation of tearing mode deceleration and licking due to eddy current induced in a conducting shell”, Physics of Plasma, 2004, vol. 11, No. 5, pp. 2156-2171.
Gnesotto, F., et al, “RFX: new tools for real-time MHD control”, 2005, retrieved from http://www.iaea.org/inis/collection/NCLCollectionStore/_Public/36/080/36080672.pdf, pp. 1-8.
Related Publications (1)
Number Date Country
20180323007 A1 Nov 2018 US
Provisional Applications (1)
Number Date Country
62160421 May 2015 US
Continuations (1)
Number Date Country
Parent PCT/US2016/031539 May 2016 US
Child 15808803 US