US3015618A - Apparatus for heating a plasma - Google Patents

Apparatus for heating a plasma Download PDF

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US3015618A
US3015618A US745778A US74577858A US3015618A US 3015618 A US3015618 A US 3015618A US 745778 A US745778 A US 745778A US 74577858 A US74577858 A US 74577858A US 3015618 A US3015618 A US 3015618A
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plasma
magnetic field
ion
ions
tube
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Thomas H Stix
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Priority to NL240726A priority patent/NL240726A/xx
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    • GPHYSICS
    • G21NUCLEAR PHYSICS; NUCLEAR ENGINEERING
    • G21BFUSION REACTORS
    • G21B1/00Thermonuclear fusion reactors
    • G21B1/05Thermonuclear fusion reactors with magnetic or electric plasma confinement
    • G21B1/055Stellarators
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E30/00Energy generation of nuclear origin
    • Y02E30/10Nuclear fusion reactors

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  • This invention relates generally to a method and apparatus for transferring energy to a plasma immersed in a confining magnetic field and particularly to a method and apparatus for heating a plasma of low atomic number ions to high temperature by transfer of energy to plasma resonances.
  • this invention involves method and apparatus for establishing a plasma confining magnetic field in an evacuated zone, establishing a plasma immersed in the field and transferring energy from 'a resonating field to a plasma resonance.
  • a variation of this invention involves transferring energy from a resonating fieldlto the plasma at the ion cyclotron frequency of the plasma ions.
  • Another variation involves generating ion cyclotron waves in the plasma by a resonating field having a frequency below the ion cyclotron frequency of the plasma ions and thermalizing the energy in the waves.
  • ion cyclotron motions and ion cyclotron waves are excited in a plasma of approximately cylindrical cross section immersed in a strong, axial magnetic field by a resonating section having an induction coil surrounding the plasma.
  • the coil is made up of helical sections, and the azimuthal direction of current flow is caused to alternate every half wave length in the coil axial direction.
  • the helical sections are connected electrically in a series parallel pattern, and their total inductance is resonated with a capacitor network by a radiofrequency voltage generator.
  • the current inthe induction coil varries periodically With both time and distance along the direction of the plasma confining magnetic field.
  • the radiofrequency cur rent in the induction coil induces an electric field in the plasma.
  • the frequency and wave length of the electric field are chosen close to a frequency and wave length of a resonance in the plasma so that it will be properly excited.
  • the periodicity with distance pf the resonating field permits electrons to flow along the lines of force and thereby cancel out the undesired ion space charge.
  • the electrons in an adjacent sector of the resonating field having the required periodicity move toward the ions of the other sector separated from their plasmaelectrons.
  • An object of this invention is to provide method and apparatus for heating a plasma.
  • Another object of this invention is to provide method and apparatus for heating a plasma immersed in a confiningmagnetic field by exciting natural resonances in the plasma.
  • a further object of this invention is to provide method and apparatus for heating the plasma of a high temperature reactor in which the plasma is immersed in a confining magnetic field.
  • a first additional object of this invention is to provide method and apparatus for heating a plasma immersed in a confining magnetic field by varying a resonating magnetic field periodically in time in a generating section of the confined plasma at a frequency approximately equal to the ion cyclotron frequency of the ions in the plas-
  • a second additional object of this invention is to provide method and apparatus for generating waves in a plasma immersed in a confining magnetic field by varying a resonating magnetic field periodically in time in a generating section of the confined plasma at a frequency approximately equal to the frequency for which the plasma has a natural resonance such as the natural resonances of ion cyclotron waves and torsional and compressional hydromagnetic waves.
  • a third additional object of this invention is to provide method and apparatus for heating a plasma immersed in "a confining magnetic field by causing thermalization of ion cycylotron motions and/or ion cyclotron waves through collisions of ions of different ratios of ion charge to ion mass.
  • a fourth additional object of this invention is to provide method and apparatus for heating a plasma immersed in a confining magnetic field by causing ion cyclotron waves to propagate into a thermalizing section wherein the plasma-confining magnetic field diminishes gradually in intensity along the lines of force and wherein thermalization of the ion cyclotron wave energy takes place.
  • a fifth additional object of this invention is to proyide method'andap'paratus for heating a plasma immersed in a confining magnetic field and temporarily restrained in its movement along the lines of force of the confining magnetic field through the use of magnetic mirrors by varyi'ng a resonating magnetic field periodically in time in a generating section of the confined plasma at the frequency of a natural resonance in the plasma.
  • FIGURE 1 is a diagrammatic view, partially cut away, of a high temperature reactor of the stellarator class in accordance with this invention showing the electrical windings for both a rmonating section and a thermalizing section.
  • FIGURE 2 is a schematic circuit diagram illustrating in simplified fashion the nature of the electrical windings of an embodiment of the present invention and the manner in which they are energized.
  • FIGURE 3 illustrates diagrammatically one manner of formingQan electrical winding in accordance with this invention.
  • FIGURE 4 is a line drawing illustrating the manner in .which 'the'intensi-ty of the confining magnetic field varies in different portions of a plasma-heating device in accord- .ance' with this invention.
  • FIGURE 5 is a graph showing the variation of the plasma power absorption for two ion species, helium and hydrogen, as a function of the strength of the confining field foraparticular exciting frequency.
  • a plasma is a gaseous state of matter in which some ,or all ofthe atoms are ionized and the total ion charge is neutralized by electrons.
  • twoions of a plasma comprising ions of low atomic number elements such as deuterium and/ or tritium collide
  • the value of the probability increases as the relative energy of the two nal energy transferred to the plasma at a threshold plasma temperature and exceeds it above the threshold.
  • the relative energy of many colliding ions must be large. Energetic collisions of ions in a plasma occur when external energy transferred to the plasma has been randomized or thermalized among the ions thereof.
  • the energy of a plasma embodied in the motion of its ions is randomized or thermalized when the ions move in a nonorganized or non-cooperative manner. Wave or oscillation motion of ions in a plasma is termed a cooperative process.
  • a plasma can have a great amount of stored energy without having a high temperature.
  • a high temperature of a plasma results from a great amount of energy being in random motion of its electrons and ions.
  • Ions and electrons having a transverse component of motion across the lines of force of a magnetic field tend to gyrate about the lines of force.
  • a plasma is immersed in a confining magnetic field when its ions and electrons, through their gyration about the lines of force, are temporarily localized.
  • the transverse gyration of an ion in a confining magnetic field is termed its ion cyclotron motion.
  • the frequency of an ion cyclotron motion, f cyclomn is given by the expression z eBg 21rm c f ion eye lotron where:
  • the resonances include ion cyclotron motions, ion cyclotron waves and torsional and compressional hydromagnetic waves.
  • the resonances include ion cyclotron motions, ion cyclotron waves and torsional and compressional hydromagnetic waves.
  • ion cyclotron wave refers to a natural oscillation or wave in a plasma which is immersed in a confining magnetic field, where the motion of the plasma ions taking part in the natural oscillation or wave is primarily transverse to the lines of force of the confining magnetic field, where the wave length (measured along a line of force) is relatively short, and where the frequency is slightly below the ion cyclotron frequency for the ions.
  • Ion cyclotron waves are excited in the plasma by a resonating field having frequencies slightly below the ion cyclotron frequency and relatively short wave lengths (wave length measured along a line of force).
  • the short wave length is required because an undesirable ion space charge, which results from the wave motion, is thereby neutralized by electrons flowing along the lines of force.
  • the inductive effect of this neutralizing electron current lowers the resonant frequency of the ion cyclotron wave below the ion cyclotron frequency and decreases the plasma heating effect of the ion cyclotron wave.
  • the amount by which the resonant frequency is lowered becomes appreciable if the wave length is not short.
  • a very similar inductive effect reduces the amount of heating of the ions which is achieved with a given induced electric field.
  • Ion cyclotron waves and torsional hydromagnetic waves correspond to the same root of a general dispersion relation, e.g., equation 10 of this article, whereas compressional hydromagnetic Waves correspond to a different root.
  • a dispersion relation for an oscillation or wave in a plasma gives the relationship between the frequency and wave length thereof.
  • Ion cyclotron waves and torsional hydromagnetic waves have different sets of values of the parameters such as frequency, Wave length, gas density and magnetic field strength.
  • a torsional hydromagnetic wave may be converted in a continuous fashion into an ion cyclotron wave by gradual adjustments of these parameters.
  • included in the meaning of the term ion cyclotron wave are those Waves which can in this continuous fashion be, in principle, converted into ion cyclotron waves with properties and parameters as described in the referenced Stix article.
  • the ion cyclotron motions and the ion cyclotron waves are of especial interest for the heating of a plasma of a high temperature reactor. Radiofrequency energy in a resonating field is transferred into these plasma resonances in a generating section in accordance with this invention.
  • the energy stored in the plasma resonances can, in accordance with this invention, be thermalized extremely rapidly into ion motions which are transverse to the magnetic lines of force with effectively random phases and amplitudes to heat the plasma.
  • the resonant frequency for ion cyclotron waves is given approximately by I 1 f fion cyclotron T/ f cyclotron is the same as in Equation 1 above,
  • the thermalization of energy of organized ion cyclotron motions may take place through the process of cyclotron damping, as described hereinafter, in approximately the time required for ion-ion collisions or the time required for ions to move along a line of force through the heating region whichever is shorter.
  • the thermalization of ion cyclotron waves may also occur by cyclotron damping if the frequency of the oscillation is sufficiently close to the ion cyclotron frequency of plasma ions.
  • cyclotron damping A brief description of the process termed cyclotron damping follows. Ions in a confining magnetic field move in a helical path. They spiral around a magnetic line of force with a frequency which is called their ion cyclotron frequency (Equation 1), and move in an unrestrained manncr along the line of force. An ion may be accelerated by an electric field, and if an ion which has an oscillatory motion is accelerated by an oscillating electric field in such a manner that the oscillatory acceleration of the ion is in phase with the oscillatory velocity of the ion, the ion will gain energy.
  • Equation 1 ion cyclotron frequency
  • an ion gains energy in the oscillatory electric field of a cyclotron
  • an ion in a plasma can gain energy from an electric field which oscillates in the plasma with a frequency approximately equal to ion cyclotron frequency.
  • the electric field in the plasma also has a periodic spatial variation (distance measured along a line of force)
  • an ion traveling along a line of force will feel the electric field at a different frequency than the electric field frequency because of Doppler efiect (the apparent frequency variation which one notices when approaching and then leaving a musical tone producer, as when passing a ringing bell while riding on a train is due to the Doppler effect).
  • ions pass out of the region of acceleration, or if the ions suffer slight changes of velocity along the lines of force due to collisions with other ions, this transverse energy becomes partially thermalized in the sense that the resultant distribution of transverse energy and velocities will contain almost random phases and amplitudes.
  • the electric field is produced by an ion cyclotron wave, the absorption of .energy from the wave by ions causes the wave to damp out with respect to either time or distance or with respect to both.
  • the electric field may alternatively be simplythe induced field of an induction coil. In either case, cyclotron damping is the absorption of energy from the electric field by those ions which pass through the electric field with just the proper velocities along the lines of force that they feel the electric field at their own ion cyclotron frequencies.
  • Thermalization of both ion cyclotron motions and ion cyclotron waves may also take place through collisions of charged particles of different mass. While ion-electron collisions transform the energy of organized plasma motion into random motion at a relatively slow rate, a faster thermalization occurs if the ion cyclotron motions or ion cyclotron waves are excited for one ion species in a plasma containing two or more species of ions such as deuterium and tritium. When the plasma contains a mixture of two or more ionspecies with different charge-tomass ratios, the collective motion of the different ion species will be very different. The amplitude of collective .motion will be much larger for the resonant ions, and
  • thermalization will occur through collisions of resonant and non-resonant ions.
  • the excitation of a very short Wave length resonance in a plasma by a correspondingly short wave length induction coil generally has a poor efficiency of transfer of radiofrequency power from the coil to the plasma. Yet the wave length for which the power transfer is efficient may be so long that thermalization of the wave energy will take place only very slowly in the plasma within. the induction coil. In an embodiment of this invention, the wave length of the induction coil is such that the transfer is efficient.
  • a thermalizing section is provided adjacent an end of the induction coil into which ion cyclotron waves are caused to propagate. In the thermalizing section there is a region of slowly decreasing magnetic field in the direction away from the induction coil.
  • phase mixing gives effective randomization of the ion motions and so there results a heating of the plasma.
  • This invention includes method and apparatus for: establishing a confining magnetic field which is unidirectional and approximately static in a zone which has been evacuated to a high vacuum; admitting a pure gas of low atomic number atoms into the zone; forming a plasma in the zone; establishing a resonating field in a generating section of the zone; and varying the resonating field at a frequency approximately equal to the ion cyclotron frequency of the ions in the plasma whereby the energy is transferred to the ions.
  • An aspect of this invention includes the apparatus and method where the resonating field in the generating section is caused to vary at a frequency approximately equal to the frequency at which the plasma has a natural resonance, such as the resonances of ion cyclotron waves and torsional and compressional hydromagnetic waves whereby such Waves are generated and energy is transferred to the plasma.
  • the generating section is of a particular design, hereinafter called a periodic generating section.
  • the intensity of the resonating field varies periodically with distancemeasured along the lines of force of the confining magnetic fieldand periodically with time.
  • This distance periodicity is the same as that of the oscillatory motions induced in the plasma.
  • the induced motions have preferentially a periodicity with a distancerneasured along a line of force. Thereby energy is transferred to the plasma.
  • Still another aspect of this invention is apparatus and method for partial thermalization or randomization of ion cyclotron motions and/or ion cyclotron waves incorporating a plasma composition of ions/with different ratios of ion charge (Z e) to ion mass (m in which the waves and/or motions are induced at a frequency which is approximately equal to the ion cyclotron frequency of only one of the constituent ion types whereby theenergy of the waves and/or motions is partially thermalized by collisions between resonant and non-resonant ions thereby heating the plasma.
  • Z e ion charge
  • m ion mass
  • a further aspect of this invention includes apparatus for the partial thermalization or randomization of ion cyclotron waves in which an ion cyclotron wave thermalizing section is established adjacent the generating section, and through this thermalizing section pass. some or all of the lines of force of the confining magnetic field which have also passed through'the generating section.
  • the thermalizing section the confining magnetic field is caused to diminish gradually in intensity with increasing distance from the generating section.
  • the ion cyclotron waves are propagated out of the generating section into the thermalizing section and therein undergo a change of character with increasing distance from the generating section, namely, their wave length decreases and the ratio of ion cyclotron wave frequency to the local ion cyclotron frequency approaches unity.
  • a change of character with increasing distance from the generating section, namely, their wave length decreases and the ratio of ion cyclotron wave frequency to the local ion cyclotron frequency approaches unity.
  • a plasma is immersed in a main confining magnetic field in which the movement of its ions is; temporarily restrained by magnetic mirrors.
  • a magnetic mirror section is adjacent to the thermalizing section, and the magnetic field therein is caused to attain a value significantly higher than the lowest value of the flux density of the confining magnetic field in the generating or in the thermalizing section, the latter sections all as aforesaid.
  • a plasma may be temporarily confined to the 7' spatial region between the two mirror sections.
  • a mirror section near only one end of a generating section, or with mirror sections of unequal strength near the ends of a generating section i.e., the peak confining magnetic field strength in the two mirror sections is of unequal strength
  • a plasma will diffuse or flow away from one end of the generating section faster than it diffuses or flows away from the other.
  • Such an apparatus and method may be used to pump a gas from one spatial region to another and to separate ions of different charge-tomass ratios. It may also be used in an ion propulsion rocket motor to impart momentum to the current carrying conductors which produce the magnetic mirror fields.
  • the excitation of particle and plasma resonances by transfer of energy to the plasma in accordance with this invention is applicable to purposes other than the heating of the plasma.
  • One such use is the generation and detection of resonances such as torsional and compressional hydromagnetic waves and ion cyclotron waves and motions as a diagnostic technique. This yields information on those parameters of the plasma and its environment which affect the character of the resonances. Typical parameters would be the density distribution of the various ion species in the plasma, the electron and ion temperatures and the magnetic field strength.
  • the waves may be detected through their magnetic and electric fields, and for detection, a magnetic pickup coil may be used which is in, out of, or surrounding the plasma.
  • the main problems involved in the development of a high temperature reactor to provide energy from selfsustaining nuclear reactions in a plasma relate to stable confinement of the plasma away from material objects, heating of the plasma to high temperature, and removal of impurities tending to contaminate the plasma. These problems and their solutions are interrelated.
  • This invention relates generally to the confinement, heating and impurity problems and provides specifically a solution to the heating problem.
  • This invention is particularly suitable for heating a plasma of a high temperature reactor of the stellarator class described in co-pending applications of Lyman Spitzer, Jr., S.N. 688,089 and SN. 705,071. It is, however, not limited to use in this class of reactor and may, for example, be utilized for heating the plasma of a reactor of the pyrotron class described in the referenced Post application.
  • a high temperature reactor of the stellarator class incorporates an endless, torus-like tube within which a fully ionized, high temperature plasma is confined.
  • the plasma is confined within the tube by a static, unidirectional, magnetic field established by two different types of electrical windings on the tube.
  • Such an externally established magnetic field having a rotational transform with a radial variation in a torus-like tube, can stably confine a plasma away from the tube wall.
  • the tube is evacuated to a high vacuum, and a pure gas of reactive atoms of controlled composition is admitted therein.
  • the gas is initially ionized to a plasma by a radiofrequency discharge or a high electric field pulse. Thereafter the ionized gas is raised to a high temperature by externally applied means.
  • At least one divertor is provided in the stellarator reactor tube for removing impurity ions from the plasma.
  • Impurity ions comprise those ions which are close to the tube wall and are derived both from the plasma and by bombardment of the tube wall by energetic particles.
  • the impurity ions are undesirable for a plasma because they are cold, have a high atomic number or are reactants.
  • In the divertor there is an electrical winding energized oppositely to the windings that produce the main confining magnetic field.
  • reactive particles the injected gas atoms and ions of the plasma prior to their entering into reactions
  • reactants the resultant particles and radiation
  • the divertor winding bends outward the main confining magnetic field lines near the wall of the torus so that these field lines pass into an enlarged section of the torus.
  • This section or divertor chamber has an annular, nonmagnetic, conductive collector plate whose inner radius is at least as large as the minor radius of the torus.
  • the magnetic lines of the main confining magnetic field which are bent into the divertor chamber, pass through the collector plate and then reenter the reactor tube.
  • the impurity ions (which are adjacent to the torus wall) follow the magnetic lines into the divertor and are prevented by the collector plate from reentering the reactor tube. They are removed from the divertor by a vacuum pump.
  • a neutron moderating means and coolant are placed near the outer wall of the stellarator tube to absorb energy released therein in the form of energetic particles and electromagnetic radiation.
  • FIGURE 1 there is shown a toruslike, non-magnetic tube 10 defining an endless chamber 11. It is formed of two equal length parallel sections 12 and 14 joined at their respective extremities by semi-circular sectors 16 and 118.
  • a radial tubular duct 21 into sector 16 serves both as an inlet for reactive gas atoms 23 from a reactive-gas source, not shown, and for evacuation of chamber 11 to a high vacuum, such as lO millimeters of mercury, for example, by a vacuum pump means, not shown.
  • a toroidal magnetic field is established everywhere in the chamber 11 by an electrical Winding 20 (a portion thereof being Shown on each semicircular sector 16 and 18) energized in a conventional manner by a direct voltage source, not shown.
  • Electrical winding 20 is wound over tube 10 throughout its length except as later described. The lines of force produced by this winding are continuous around the torus.
  • Helical windings 22 underlie winding 20 over a part of the length of tube 10. They are preferably four or six in number and are evenly spaced about tube 10 as viewed at cross section 25.
  • Adjacent helical windings 22 are energized oppositely and impart to the axial field established by winding 20' a field component such that the resultant field is characterized by a rotational transform having a radial variation.
  • each magnetic line established by windings 20 and 22 in cooperation, after it has made one traversal of the tube 10, has a particular angular displacement instead of closing on itself. Because of the radial variation, this angular displacement increases as the distance of a field line from the magnetic axis 24 of tube 10.
  • the radial variation is a gradient of the aforesaid angular displacement with distance from the magnetic axis such that magnetic lines farther from the axis 24 of chamber 10 wind about the axis 24 in tighter and tighter helices.
  • An annular ferrite ring 26 is disposed about tube 10 at section 18 thereof. Electrical winding 28 is wound on ring 26. A radiofrequency voltage appears along axis 24 of chamber 11 when winding 28 is energized at its terminals 30 and 32 by a radiofrequency voltage source, not shown. There occurs as a result thereof a radiofrequency discharge in the gas atoms 23 which ionizes them to a plasma.
  • a laminated iron annular ring 34 is disposed about straight section 14 of tube 10 for ohmic heating of the plasma in chamber 11. Wound upon ring 34 is an electrical winding 36 which is energized at its terminals 38 and 40 by an audiofrequency voltage source, not shown. Laminated iron ring 34 and its energized winding 36 cause ohmic heating of the plasma by ohmic losses therein.
  • a divertor 42 is located in straight section 14 of tube provided it is greater than one.
  • torus wall to insulate winding 68 from the plasma.
  • .It comprises a housing 46 defining chamber 48, in effect, an enlargement in the chamber 11.
  • Chamber 48 is evacuated by a vacuum pump, not shown, through a port 50.
  • Electrical winding 52 wound about tube 10 is electrically energized by a direct voltage source (such as the same voltage source used to energize winding 20) in the direction of arrow 54 and provides a magnetic field in chamber 48 which locally distorts the confining magnetic field represented by magnetic field lines 17. This causes the confining magnetic field lines near to the wall of tube 10 to be bent into chamber 48 as shown by typical magnetic field lines 56 and 58.
  • Parallel, non-magnetic metallic impurity-ion-collector plates 69 and 62 form an enclosure 63 within which electrical winding 52 is disposed and divide chamber 48 into communicating subchambers 64 and 66.
  • Magnetic field lines 56 and 58 thus enter subchamber 64, pass through collector plates 60 and 62, enter subchamber 66 and reenter tube 16 therefrom.
  • Generating section 103 for heating a plasma immersed in a confining magnetic field in accordance with this invention is located in straight section 12 of tube 10. Generally, it comprises a housing 164, an insulating tube 70 within the housing, and an induction coil 68 wound on the tube.
  • FIGURE 2 is a schematic diagram of a portion of an electrical circuit for the generating section 103 (FIGURE 1), there is shown electrical winding 68 wound on insulating tube 70.
  • Winding 68 comprises winding sectors 72, 74, Y76 and 78.
  • Outer winding sectors 72 .and 78 (with regard to the ends of tube 70) are wound in one direction about insulator tube 70, and inner winding sectors 74 and 76 are wound in the opposite direction about the tube axis, e.g., clockwise and counterclockwise viewed from :one end of tube 70, respectively.
  • radiofrequency generator 80 is energized by radiofrequency voltage generator 80 through high voltage conductor 82 connected between plates 84 98.
  • The'capacitors 88 and 910 are selected so as to match the input impedance of coil 68 ,to the output impedance ofradiofrequency generator 80.
  • radiofrequency generator 80 causes coil 68 to produce a varying magnetic field (periodic both in time and distance) along-the axis 24 of insulator tube 70.
  • insulatortube 7t and electrical winding 68 are disposed within chamber 102 of generating section housing-104 and coaxial with straight section 12. Insulator tube 70 is sealed to the However, winding 68 may otherwise be insulatedfrom the plasma, e.g., as by using insulated wire for winding 68.
  • Generating section housing 164 includes annular ringlike end plates 1'06 and 108 hermetically sealed tosec- -tion 12 of tube 10. Additionally, housing 104 has an outer, cylindrical, non-magnetic wall 110 and aninner,
  • a magnetic field gradient-producing winding 121 in thermalizing section 123 is shown wound on tube 10 adjacent each end .of generating section 103. It comprises a plurality of turns with gradually increasing spacing between the turns, i.e.,, along the axis 24 of tube 10 away from the end of generating section 103. It causes the confining magnetic field in tube 10 to drop off approximately 20% in intensity over the length of ther malizing section 123.
  • Winding 121 is part of magneticfield-producing winding 20 and may be commonly energized.
  • FIGURE 1 a mirror magnetic field winding 122 in mirror section 126 is shown wound on sections 16 and 18 of tube 10.
  • Mirror winding 122 is part of winding 20 and may be commonly energized and produces high flux density over mirror section 126 as compared to the plasma confining field elsewhere in tube 10.
  • Helical windings 22 underlie both magnetic-gradient producing winding 121 and mirror winding 122.
  • sufficient radial transform and radial variation thereof may be imparted to the field produced by coil 20 on other portions of the tube 1% and so helical windings 22 are not required on thermalizing section 123 and mirror section 126.
  • the reactor shown in FIGURE 1 is operated as follows: Tube 14 is evacuated via tube 21 and reactive gas atoms 23 are introduced into chamber 11. Axial confining magnetic field electrical winding 20 and cooperating parts thereof, 22, 1 14, 121, 12.2 and 52 are energized by a voltage means, not shown, approximately at the'same time as the reactive atoms 23, e.g., deuterium, are introduced into chamber 11. Then, the reactive atoms are initially fionized to a plasma by a radio-frequency discharge produced by ferrite ring 26 as aforesaid. The ohmic heating ring 34 is used to bring the plasma to a state of almost complete ionization and to provide some heating of the plasma. The amount of ohmic heating needed is dependent upon the particular conditions of operation of the reactor such as pressure and temperature. Next, the plasma isheated by means of generating section 103.
  • electrical winding 68 taken together with capacitors 88 and comprises a resonant circuit energized by radiofrequency voltage source 80.
  • sectors 72 and 76, and sectors 74' and 78 carry electric current in opposite directions about axis 24 of tube 70, respectively, the fields producedthereby are alternately out of phase. Thatis, e.g., considering the fields at a particular instant, the fields produced by sectors 72' andg76 are to the right and the fields produced by sectors "121 and 122 are not energized. However, there are then provided in their respective locations, sectors of the main field winding 20.
  • radiofrequency generator 80 establishes a varying magnetic field in chamberll through winding 68. This field is at the resonant frequency for cyclotron waves or torsional hydromagnetic waves.
  • electrical windings 121 and 122 of thermalizing section 123 and mirror section 126, respectively, are energized either at one or both ends of generating section 103.
  • FIGURE 4 is used to illustrate the effect on the plasma ionsof the main confining magnetic field in the tube 70 produced by Winding114, the gradient magnetic field within winding 121, and the mirror field within winding 122'.
  • the block in FIGURE 4 represents generating secdistance from the center of the generating section 103.
  • the position along the Y axis measures the reciprocal of the intensity of the confining magnetic field. The larger the Y-axis coordinate, the less is the magnetic intensity.
  • coil 68 is energized (by radiofrequency voltage source 80) at a frequency appropriate for the generation of ion cyclotron or torsional hydromagnetic waves in tube 70 in a region of relatively high magnetic field strength.
  • ion cyclotron waves propagate along magnetic lines of force through the thermalizing section 123.
  • the intensity of the confining magnetic field is decreasing gradually with distance measured along a line of force from the generating section 103, e.g., a 20% decrease in intensity from the generating section 103 to the mirror section 126.
  • This variation is produced by coil 121 having a greater and greater separation between turns away from the generating section 103.
  • the ion cyclotron wave wavelength gradually decreases.
  • FIGURE 5 presents experimental data on the absorption of energy by a plasma of helium and hydrogen ions from the induction coil 68.
  • the experiment was performed at Princeton University on a model of the stellarator.
  • the frequency of the resonating field was 10.16 megacycles and its wave length was 9 inches.
  • the abscissa of FIGURE 5 gives the strength of the confining magnetic field in kilogauss, and the ordinate W (on a non-linear scale increasing toward the abscissa) gives the ratio of the radiofrequency power absorbed by the plasma to the radiofrequency power that would have been ohmic loss if the figure of merit Q of the induction coil 68 were equal to 300.
  • a value of W equal to 1 indicates a power-transfer efficiency of 50%, and higher values of W indicate higher power-transfer efficiencies.
  • the vertical lines 150 and 152 indicate the values of the magnetic field for which the radio-frequency of generating section 103 is equal to the ion cyclotron frequency for hydrogen (approximately 6.6 kilogauss) and the doubly ionized helium (approximately 13.1 kilogauss), respectively.
  • peaks 154 and 156 shows that appreciable fractions of the radiofrequency power applied to coil 68 were absorbed by the plasma preferentially at and in the neighborhood of the ion cyclotron frequencies of hydrogen and helium, respectively.
  • Apparatus for transferring energy to a plasma and heating the plasma comprising a cylindrical torus-like tube defining a uniformly evacuated endless chamber, means for establishing a quasi-static plasma-confining magnetic field in said chamber, means establishing a plasma of ions and electrons immersed in said magnetic field, an induction coil around said tube having periodic oppositely directed windings, a resonating magnetic second field generating section operable with said coil to produce a in said chamber ion accelerating second fields having a time and spatial periodicity along the lines of force of said confining magnetic field so as to excite hydromagnetic waves in said plasma, and means for thermalizing the energy in said hydromagnetic wave including means for establishing a magnetic field gradient in said confining magnetic field to heat said plasma by cyclotron damping.
  • Apparatus for transferring energy to a plasma and heating the plasma comprising means for establishing a plasma-confining magnetic field in a uniformly evacuated zone, means for immersing a plasma of ions and electrons in said field, an induction coil around a portion of said field having periodic oppositely directed windings, means for energizing said coil to cause the direction of current flow to alternate periodically with distance in the coil axial direction, and to have a time periodicity to excite ion cyclotron motions and ion cyclotron waves in said plasma, and a thermalizing section having electrical winding means for producing a magnetic gradient in said confining magnetic field to cause the flux density of said confining field to decrease gradually over said thermalizing section whereby the energy in said ion cyclotron motions and ion cyclotron waves is thermalized.
  • Apparatus for transferring energy to a plasma and heating the plasma comprising means for establishing a plasma-confining magnetic field in a uniformly evacuated zone, means for immersing a plasma in said field, an induction coil around a portion of said field having periodic oppositely directed series connected windings, means for energizing said coil to cause the direction of current flow to alternate periodically with distance, in the coil axial direction, and to have a time periodicity to excite ion cyclotron motions and ion cyclotron waves in said plasma, and mirror sections adjacent opposite ends of said coil having electrical winding means for locally increasing the flux density of said confining magnetic field to relatively high field strength to cause mirror confinement of said plasma.
  • Apparatus for transferring energy to a plasma and heating said plasma comprising means for establishing a plasma-confining magnetic field in a uniformly evacuated zone, means for immersing a plasma in said field, an induction coil around a portion of said field having periodic oppositely directed windings, means for energizing said coil to cause the direction of current flow therein to alternate in the coil axial direction, and to have a time periodicity to excite ion cyclotron motions and ion cyclotron waves in said plasma, a thermalizing section including means for producing a magnetic gradient in said confining magnetic field to cause the flux density of said confining field to decrease gradually over said thermalizing section whereby the energy in said ion cyclotron motions and ion cyclotron waves is thermalized, and mirror sections adjacent opposite ends of said coil including means for locally increasing the flux density of said confining magnetic field to a relatively high field strength to cause mirror confinement of said plasma.
  • a high temperature reactor of the type having a cylindrical tube defining a uniformly evacuated chamber, means for establishing in said chamber a unidirectional substantially static magnetic field, and means immersing a plasma of ions and electrons in said magnetic field
  • the improvement comprising an induction coil encircling a portion of said tube and having periodic oppositely directed windings, a capacitor network having a radio-frequency source for energizing said coil to excite in said plasma electric fields having a time and spatial periodicity to excite ion cyclotron motions and ion cyclotron waves in said plasma, and a thermalizing section having windings around said tube with gradually decreasing spacing be ginning adjacent said induction coil for thermalizing the energy in said motions and waves to heat said plasma to a high temperature.
  • a high temperature reactor comprising a cylindrical torus-like tube defining an endless uniformly evacuated chamber, a first coil radially encircling said tube, said first coil extending axially around the entire length of said tube and having first and second windings, said first windings having gradually increasing spacing and forming a thermalizing section, said second windings having even spacing and forming a generating section connected in series with said thermalizing section, a second coil radially encircling said tube having helical third windings extending axially along only a portion of the length of said tube and being operable with said first coil to produce a unidirectional substantially static magnetic field with a rotational transform and radial variation, means for immersing a plasma of ions and electrons in said magnetic field, an induction third coil adjacent said second windings of said first coil and extending coaxially therewith to the place where the 1st windings of said first co-il begin to gradually increase in spacing, said third coil having helical fourth windings oppositely directed

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US745778A 1958-06-30 1958-06-30 Apparatus for heating a plasma Expired - Lifetime US3015618A (en)

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US745778A US3015618A (en) 1958-06-30 1958-06-30 Apparatus for heating a plasma
GB15664/59A GB867315A (en) 1958-06-30 1959-05-07 Method and apparatus for heating a plasma
DEU6275A DE1186155B (de) 1958-06-30 1959-06-11 Verfahren und Vorrichtung zum Erhitzen eines Plasmas
NL240726A NL240726A (de) 1958-06-30 1959-06-30

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Cited By (18)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3085173A (en) * 1961-08-17 1963-04-09 Gibson Gordon Apparatus for trapping energetic charged particles and confining the resulting plasma
US3088894A (en) * 1960-12-23 1963-05-07 Harold R Koenig Confinement of high temperature plasma
US3160566A (en) * 1962-08-09 1964-12-08 Raphael A Dandl Plasma generator
US3219534A (en) * 1964-10-26 1965-11-23 Harold P Furth Plasma confinement apparatus employing a helical magnetic field configuration
US3278384A (en) * 1965-04-13 1966-10-11 Lenard Andrew Negative "v" stellarator
US3290219A (en) * 1963-09-19 1966-12-06 Gen Electric Plasma containment method and apparatus
US3442758A (en) * 1963-08-07 1969-05-06 Litton Industries Inc Containment of a plasma by a rotating magnetic field
US3668066A (en) * 1970-02-18 1972-06-06 Atomic Energy Commission Dynamic stabilizer for plasma instabilities to improve plasma confinement and to increase plasma density
US4149931A (en) * 1973-07-16 1979-04-17 The United States Of America As Represented By The United States Department Of Energy Divertor for use in fusion reactors
US4302284A (en) * 1979-01-29 1981-11-24 General Atomic Company Helical field stabilization of plasma devices
US4710339A (en) * 1984-08-27 1987-12-01 The United States Of America As Represented By The United States Department Of Energy Ion cyclotron range of frequencies heating of plasma with small impurity production
USH936H (en) 1986-09-25 1991-07-02 The United States Of America As Represented By The United States Department Of Energy Thermonuclear inverse magnetic pumping power cycle for stellarator reactor
WO2016061001A3 (en) * 2014-10-13 2016-07-07 Tri Alpha Energy, Inc. Systems and methods for merging and compressing compact tori
US10096454B2 (en) * 2014-03-11 2018-10-09 Tokyo Electron Limited Plasma processing apparatus
US10418170B2 (en) 2015-05-12 2019-09-17 Tae Technologies, Inc. Systems and methods for reducing undesired eddy currents
US10440806B2 (en) 2014-10-30 2019-10-08 Tae Technologies, Inc. Systems and methods for forming and maintaining a high performance FRC
US10446275B2 (en) 2011-11-14 2019-10-15 The Regents Of The University Of California Systems and methods for forming and maintaining a high performance FRC
US20230317304A1 (en) * 2022-03-14 2023-10-05 The Trustees Of Princeton University System and method for stellarator neutron source

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DE1241004B (de) * 1961-10-13 1967-05-24 Ernest Lagelbauer Verfahren zur Erzeugung eines Hochtemperatur-plasmas unter Verwendung eines magnetischen Spiegelsystems

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US2826708A (en) * 1955-06-02 1958-03-11 Jr John S Foster Plasma generator

Cited By (27)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3088894A (en) * 1960-12-23 1963-05-07 Harold R Koenig Confinement of high temperature plasma
US3085173A (en) * 1961-08-17 1963-04-09 Gibson Gordon Apparatus for trapping energetic charged particles and confining the resulting plasma
US3160566A (en) * 1962-08-09 1964-12-08 Raphael A Dandl Plasma generator
US3442758A (en) * 1963-08-07 1969-05-06 Litton Industries Inc Containment of a plasma by a rotating magnetic field
US3290219A (en) * 1963-09-19 1966-12-06 Gen Electric Plasma containment method and apparatus
US3219534A (en) * 1964-10-26 1965-11-23 Harold P Furth Plasma confinement apparatus employing a helical magnetic field configuration
US3278384A (en) * 1965-04-13 1966-10-11 Lenard Andrew Negative "v" stellarator
US3668066A (en) * 1970-02-18 1972-06-06 Atomic Energy Commission Dynamic stabilizer for plasma instabilities to improve plasma confinement and to increase plasma density
US4149931A (en) * 1973-07-16 1979-04-17 The United States Of America As Represented By The United States Department Of Energy Divertor for use in fusion reactors
US4302284A (en) * 1979-01-29 1981-11-24 General Atomic Company Helical field stabilization of plasma devices
US4710339A (en) * 1984-08-27 1987-12-01 The United States Of America As Represented By The United States Department Of Energy Ion cyclotron range of frequencies heating of plasma with small impurity production
USH936H (en) 1986-09-25 1991-07-02 The United States Of America As Represented By The United States Department Of Energy Thermonuclear inverse magnetic pumping power cycle for stellarator reactor
US10446275B2 (en) 2011-11-14 2019-10-15 The Regents Of The University Of California Systems and methods for forming and maintaining a high performance FRC
US10096454B2 (en) * 2014-03-11 2018-10-09 Tokyo Electron Limited Plasma processing apparatus
CN107006111B (zh) * 2014-10-13 2020-06-30 阿尔法能源技术公司 用于合并和压缩紧凑环的系统和方法
US10217532B2 (en) 2014-10-13 2019-02-26 Tae Technologies, Inc. Systems and methods for merging and compressing compact tori
US11200990B2 (en) 2014-10-13 2021-12-14 Tae Technologies, Inc. Systems and methods for merging and compressing compact tori
CN107006111A (zh) * 2014-10-13 2017-08-01 Tri 阿尔法能源公司 用于合并和压缩紧凑环的系统和方法
WO2016061001A3 (en) * 2014-10-13 2016-07-07 Tri Alpha Energy, Inc. Systems and methods for merging and compressing compact tori
EA034349B1 (ru) * 2014-10-13 2020-01-30 Таэ Текнолоджиз, Инк. Система для формирования, сжатия и слияния компактных тороидов плазмы
US10665351B2 (en) 2014-10-13 2020-05-26 Tae Technologies, Inc. Systems and methods for merging and compressing compact tori
US10743398B2 (en) 2014-10-30 2020-08-11 Tae Technologies, Inc. Systems and methods for forming and maintaining a high performance FRC
US10440806B2 (en) 2014-10-30 2019-10-08 Tae Technologies, Inc. Systems and methods for forming and maintaining a high performance FRC
US11337294B2 (en) 2014-10-30 2022-05-17 Tae Technologies, Inc. Systems and methods for forming and maintaining a high performance FRC
US10910149B2 (en) 2015-05-12 2021-02-02 Tae Technologies, Inc. Systems and methods for reducing undesired eddy currents
US10418170B2 (en) 2015-05-12 2019-09-17 Tae Technologies, Inc. Systems and methods for reducing undesired eddy currents
US20230317304A1 (en) * 2022-03-14 2023-10-05 The Trustees Of Princeton University System and method for stellarator neutron source

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GB867315A (en) 1961-05-03
DE1186155B (de) 1965-01-28
NL240726A (de) 1964-01-27

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