US3270243A - Apparatus for the establishment and acceleration of a narrow high current beam - Google Patents

Apparatus for the establishment and acceleration of a narrow high current beam Download PDF

Info

Publication number
US3270243A
US3270243A US97232A US9723261A US3270243A US 3270243 A US3270243 A US 3270243A US 97232 A US97232 A US 97232A US 9723261 A US9723261 A US 9723261A US 3270243 A US3270243 A US 3270243A
Authority
US
United States
Prior art keywords
electrons
housing
longitudinal axis
cathode
accelerating
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US97232A
Inventor
Donald W Kerst
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
General Dynamics Corp
Original Assignee
General Dynamics Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by General Dynamics Corp filed Critical General Dynamics Corp
Priority to US97232A priority Critical patent/US3270243A/en
Application granted granted Critical
Publication of US3270243A publication Critical patent/US3270243A/en
Assigned to GA TECHNOLOGIES INC., A CA CORP. reassignment GA TECHNOLOGIES INC., A CA CORP. ASSIGNS ENTIRE INTEREST. SUBJECT TO REORGANIZATION AGREEMENT DATED JUNE 14, 1982 Assignors: GENERAL ATOMIC COMPANY
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J3/00Details of electron-optical or ion-optical arrangements or of ion traps common to two or more basic types of discharge tubes or lamps
    • H01J3/02Electron guns
    • H01J3/029Schematic arrangements for beam forming

Definitions

  • Another object of the invention is the provision of a method of establishing and accelerating an intense beam of electrons whereby adverse space charge effects and the like are substantially eliminated.
  • a more specific object of the invention resides in a method of establishing a beam of electrons which is neutralized and confined in a narrow configuration during the passage thereof through an accelerating field.
  • FIG. 1 is a diagrammatic representation, partially in cross-section, of an apparatus which may be satisfactorily utilized to establish and accelerate a narrow high intensity beam of electrons in accordance with the provisions of this invention.
  • a preferred method of establishing and accelerating an intense beam of electrons contemplates the emission of an intense cloud of electrons by a cold cathode. Thereafter in accordance with the provisions of this invention, a dense beam is extracted from the cloud of electrons and focused in a narrow beam. The focused beam is subsequently accelerated through a glow discharge plasma containing substantially equal numbers of electrons and positive ions whereby the beam is space charge neutralized and maintained in the narrow configuration.
  • a cold emission cathode 9 which is preferably formed of an electron emitting material such as tungsten (wolfram), is suitably mounted within and in spaced relation to the wall of an evacuated accelerating tube that has an ionizable gas supplied thereto from a source 11.
  • the cathode 9 is proportioned with a sharp cone-shaped end section or tip 9a and is suspended within the accelerating tube 10 so that the longitudinal axis thereof is aligned with the longitudinal axis of the tube.
  • a terminal 12 is secured to the base of the cold emission cathode 9 and is maintained in electrical contact with the grounded wall of the accelerating tube 10 through a resistor 13.
  • a high voltage electrode 14 Positioned in spaced relation to the cathode 9, the cone-shaped tip of which is directed toward the outlet extremity of the tube 10, is a high voltage electrode 14.
  • a conductor 14a extends from the electrode 14 to a highly negative source of potential 15 through a gas-tight insulating bushing 14b that is mounted in the wall of the tube 10.
  • a trigger probe 16 is disposed between the electrode 14 and the cathode 10. This trigger probe is selectively supplied With potential from a pulsing source 17 through a conductor 16a.
  • the conductor 16a extends through a gas-tight insulating bushing 16b that is also mounted in the wall of the accelerating tube.
  • the potential difference that exists between the terminal 12 and the negative electrode 14 is insufficient to effect the establishment of an arc discharge between these members.
  • the magnitude of this potential difference is sufficient to maintain an arc discharge subsequent to the establishment thereof, which is accomplished by the selective operation of the pulsing source 17. More particularly, the magnitude and duration of the voltage pulse supplied to the trigger probe 16 is sufiicient to initiate a discharge between the probe and the terminal 12. Thereafter, as the pulse is dissipated, the high negative potential on the electrode 14 attracts and effects the transfer of the are from the pro-be 16 to the electrode. With the are established between the terminal 12 and the electrode 14, a complete path for current flow is provided from the source 15 to the grounded wall of the accelerating tube 10 through the resistor 13.
  • the passage of current through the resistor 13 results in the development of voltage thereacross.
  • the developed voltage is substantially equal in magnitude to the highly negative potential supplied by the source 15. Because the resistor is maintained in electrical contact with the cathode through the terminal 12, the negative potential developed across the resistor is supplied to the tip of the cathode 9.
  • a plate 18 is positioned in spaced relation to the highly negative cone-shaped tip of the cathode 9.
  • the plate is mounted within the accelerating tube 10 normal to the longitudinal axis thereof and is maintained in electrical contact with the grounded wall of the tube. Consequently, the plate is substantially more positive than the tip 9a of the cathode 9.
  • the unique cone-shaped configuration of the tip 9a coupled with the difference of potential between the cathode and the plate 18 results in the establishment of an intense electrical field which is concentrated at the tip of the cathode.
  • the resulting high potential gradient at the surface of the cathode 9 results in the emission of an extremely high current and intense flow of electrons away from the cone-shaped tip and toward the plate 18.
  • the electrons emitted from the tip of the cathode are passed through a circular aperture 19 which is formed in the plate 18.
  • the center of radius of the circular aperture 19 lies on a line defined by the longitudinal axis of the gas filled tube and, as illustrated, is spaced in close proximity to the cathode 9.
  • the diameter of the aperture is chosen in accordance with the calculated magnitude of the angle of spread of the electrons being emitted from the cone shaped tip of the cathode. Accordingly, substantially all of the electrons attracted toward the plate 18 pass through the aperture and into a focusing system generally designated by the numeral 21.
  • the function of the focusing system is to optimize or adjust the product of the beam diameter times the angle of spread of the electron paths.
  • the focusing system 21 includes a pair of electromagnets 22 and 23 that are supplied with power from a suitable source 24. As illustrated, these focusing members are positioned in spaced relation to the plate 18 and in alignment with the aperture formed therein.
  • the electromagnetic focusing accomplished by the members 22 and 23 substantially minimizes the spread of the beam just prior to the transmittal thereof to an accelerating section 26 of the tube 11. Accordingly, the beam advanced into the accelerating section 26 will be substantially confined to a narrow path in the region of the longitudinal axis of the tube. While in the illustrated embodiment, focusing of the beam is accomplished electromagnetically, modifications of the structural features of the focusing system 21 could be readily accomplished so that electrostatic focusing of the electron beam could also be utilized.
  • the accelerating section 26 of the tube 11 includes a plurality of ring-type magnetic cores 27 which are suspended in spaced relation to the wall of the tube and generally normal to the longitudinal axis thereof.
  • the center of each of the ring-type magnetic cores lies on the longitudinal axis of the tube, and each has a conductive member 28 wound around the entire surface thereof.
  • the conductive members 28, which are preferably wound in a single layer about the surface of the cores 27, have exciting current supplied thereto from a current source 29.
  • the current source 29 also includes a conventional high frequency current generating system which is selectively rendered effective to initiate or tickle a glow discharge in the region adjacent the longitudinal axis of the accelerating tube 10. More particularly, the intermittent passage of high frequency pulses of current through the conductors 28 results in the breaking down and ionization of the gas supplied from the source 11 to the accelerating region of the tube 10. Consequently a glow discharge plasma, which contains substantially equal numbers of electrons and positive ions is established in the region surrounding the longitudinal axis of the tube. As will be hereinafter described, this glow discharge plasma, and more accurately the positive ions of the glow discharge plasma, function to neutralize the beam of electrons transmitted through the accelerating section of the tube subsequent to the focusing thereof by the electromagnets 22 and 23.
  • both the exciting and ionizing or glow discharge-producing currents is limited so that an arc discharge is not established Within the tube. Consequently, the exciting current, which establishes the individual axial accelerating fields, and the high frequency ionizing current, which is intermittently applied to the conductors 28, coact to effect both the acceleration and neutralization of the electron beam while substantially eliminating the adverse effects which might result from the creation of an arc discharge in the tube.
  • the preionized glow discharge which can be initiated or tickled in a variety of ways, will not convert into an arc discharge for several microseconds after the main exciting or accelerating field is established. Accordingly, all of the emitted electrons will be accelerated through the glow discharge before any arc discharge is created in the tube.
  • a plurality of circular plates 33 which are electrically connected to the grounded wall of the tube and mounted generally normal to the longitudinal axis thereof, are spaced along the length of the tube from the inlet of the accelerating section 26 to the outlet of the section adjacent to the target 31.
  • One each of the plates 33 is mounted between each of the ring-type magnetic cores 27 and each has a circular aperture provided therein so that the focused electrons passing through the accelerating section are not obstructed thereby.
  • cylindrical section 34 Secured to and extending from each of the plates 33 is a cylindrical section 34 which is positioned in spaced and concentric relation to the inner surface of each of the magnetic cores 27. These cylindrical sections 34 have a diameter which is larger than the diameter of the aperture provided in each of the plates 33 but smaller than that of the inner cylindrical surface of the magnetic cores 27.
  • each of the cylindrical sections 34 normal to the longitudinal axis of the tube Extending inwardly from each of the cylindrical sections 34 normal to the longitudinal axis of the tube are a plurality of disc-like bafiie members 35.
  • the inner diameter of each of the disc-like bafile members 35 is substantially equal to the diameter of the aperture provided in the plates 33.
  • the bafile members 35 function to preclude the occurrence of an arc discharge within the tube subsequent to the preionization of the gaseous medium maintained therein. More partciularly, these bathe members limit the distance through which stray electrons can travel and further preclude the establishment of an electron avalanche and the undesirable beam destroying effects that would result from an arc discharge.
  • a plurality of metallic screen segments 36 which in a preferred embodiment of the invention are cylindrical in shape, is mounted along the longitudinal axis of the tube.
  • the screen segments are preferably positioned in electrical contact with the innermost edge of the disclike baffie members 35 and the aperture defining surfaces of the plates 33.
  • the screen segments which are concentric with the ring-type magnetic cores 27, define a cylindrical region wherein the positive ions of the glow discharge plasma effect neutralization of the beam of electrons accelerated and transmitted therethrough toward the target 31.
  • the individual screen segments 36 are spaced from each circular plate 33 associated with the following cylindrical section 34. The purpose of this spacing is to provide an eccelcrating gap 34a and to preclude short circuiting of each of the magnetic cores 27.
  • the target 31 is preferably a thin foil member which is framed across a projecting cylindrical end portion of the accelerating tube 10 normal to the longitudinal axis thereof.
  • the target is made of a material which functions to pass the narrow beam from the accelerator while precluding the scattering thereof.
  • One such material which may be satisfactorily utilized for this application is beryllium.
  • the beam which is formed and accelerated through the tube and which is transmitted therefrom through the target 31 may be utilized in any number of applications where a narrow beam of accelerated particles is required.
  • a preferred method of establishing and accelerating a high current beam of electrons and transmitting the beam through the beryllium foil target 31 is initiated by ionizing the gaseous medium confined in the region defined by the screen segments 36.
  • the ionization of the gas is effected by passing a high frequency current of preselected magnitude from the source 29 through each of the conductive members 28 that surround the ring-type magnetic cores 27. Thereafter, the passage of exciting current through the conductive members 28 results in the establishment of an accelerating electric field along the longitudinal axis of the tube.
  • the selectively operable pulsing source 17 is rendered effective to effect the establishment of an arc discharge between the terminal 12 of the cathode 9 and the electrode 14.
  • the high field established between the tip 9a of the cathode and the plate 18 results in the emission of a high current 'beam of electrons which are advanced through the aperture 19 provided in the attracting plate 18.
  • the electrons emitted from the tip of the cathode, after travelling through the aperture 19, are focused by the electromagnets 22 and 23, and the focused beam is transmitted to the accelerating section 26 of the tube.
  • the neutralizing glow discharge plasma produced near the longitudinal axis of the tube by the intermittent passage of a high frequency current through the conductor 28 effects neutralization of the beam. More particularly, as the beam is accelerated through the plasma the electrons therein are repulsed and pass through the cylindrical screen segments which are disposed in concentric fashion about the longitudinal axis of the tube. Accordingly, an abundance of positive ions formerly associated with the repulsed plasma electrons remains in the path of the beam and effects neutralization of the beam of electrons. This neutralization accomplished by the positive plasma ions substantially eliminates the intrinsic repulsive forces between beam electrons.
  • the narrow configuration thereof is maintained until the entire length of the accelerating section 26 has been traversed and the beam is transmitted through a foil target for use in some suitable external application.
  • Additional focusing of the neutralized and accelerated beam by a focusing system similar to the focusing system 21 might be required to preclude the establishment of instabilities within the beam after passing through the target 31.
  • the accelerator tube is approximately 1000 cm. in length and has a diameter of approximately 25 cm.
  • the cold cathode 9 is proportioned so that a plurality of emissions having a duration of l microsecond can be effected prior to the replacement thereof.
  • An ionizable gas which is supplied to the tube from the source 11 is maintained therein at a pressure of approximately 10- mm. or less.
  • Approximately 250 ring-type magnetic cores, which establish an electric accelerating field of approximately 20 kv./cm. within the tube and thereby effect the acceleration of the beam therein, are arranged along the length thereof so that the beam of electrons passing through the tube has approximately 5 mev. of energy imparted thereto.
  • Neutralization of a beam having a radius of approximately 1 mm. and containing 10 to 10 amperes of electrons can be effected by approximately 10 ions per cubic centimeter which are attainable in a moderate preionized glow discharge.
  • Apparatus for providing and accelerating an intense marrow beam of electrons which comprises an elongated closed cylindrical housing having a foil target mounted at one extremity thereof adjacent the longitudinal axis thereof, a cold emission cathode mounted within said housing adjacent the other extremity thereof, said cathode having an elongated cone-shaped tip directed along the longitudinal axis of said housing toward said foil target, beam focusing means positioned within said housing in coaxial relation with the longitudinal axis thereof and in spaced relation to the cone-shaped tip of said cathode, means interposed between said cathode and said focusing means for effecting a high field emission of electrons from the tip of said cathode and for directing the emitted electrons to said beam focusing means, a plurality of spacedapart ring-type cores mounted within said housing in concentric relation with the longitudinal axis thereof, said cores being disposed transversely of the longitudinal axis of said housing and spaced between said focusing means and said foil target, and means for selectively en
  • Apparatus for providing and accelerating an intense narrow beam of electrons which comprises an elongated closed cylindrical housing having a foil target mounted at one extremity thereof adjacent the longitudinal axis thereof, a cold emission cathode mounted within said housing adjacent the other extremity thereof, said cathode having an elongated cone-shaped tip directed along the longitudinal axis of said housing toward said foil target,
  • beam focusing means positioned within said housing in coaxial relation with the longitudinal axis thereof and in spaced relation to the cone-shaped tip of said cathode, a plate mounted within said housing in electrical contact therewith between said cathode and said focusing means, said plate having an aperture formed therein adjacent the longitudinal axis of said housing, means for establishing a high negative potential on said cathode relative to said plate, the substantial difference in potential between the tip of said cathode and said plate effecting a high field emission of electrons from the tip of said cathode toward said beam focusing means, a plurality of spaced-apart ringtype magnetic cores mounted within said housing in concentric relation with the longitudinal axis thereof, said magnetic cores being disposed transversely of the longitudinal axis of said housing and spaced between said focusing means and said foil target, and means for selectively energizing said magnetic cores so as to establish a glow discharge within said housing adjacent the longitudinal axis thereof and create an accelerating field in the direction of the outlet extremity of
  • Apparatus for providing and accelerating an intense narrow beam of electrons which apparatus comprises an elongated housing having a target mounted at one extremity and along the longitudinal axis thereof, a cathode mounted Within said housing adjacent the other extremity thereof, said cathode having an elongated cone-shaped tip directed along the longitudinal axis of said housing and toward said target, beam focusing means positioned wrthm said housing in coaxial relation with the longitudinal axis thereof and in spaced relation to the coneshaped tip of said cathode, means interposed between said cathode and said beam focusing means for effecting a high field emission of electrons from the tip of said cathode and for directing the emitted electrons into said beam focusing means, beam neutralizing means mounted within sald housing between said beam focusing means and said target, and means for selectively energizing said beam neutralizing means so as to establish a glow discharge within said housing adjacent the longitudinal axis thereof and create an accelerating field in the direction of said target, said glow discharge functioning to
  • Apparatus for accelerating electrons in an intense narrow beam which apparatus comprises a housing, means for supplying gas to the interior of said housing, means for lOIllZlIlg a portion of said gas within said housing, means for effecting an emission of electrons in a narrow beam directed into said gas ionized by said means for lonlzrng, and energizing means operable subsequent to said means for ionizing, said energizing means being operable to establish an electron accelerating field within said ionized gas in the path of said narrow beam of electrons to accelerate the electrons in said beam, said electrons produced by the ionizing of said gas being repelled out of the path of said beam by electrons in said beam, leaving unrepulsed positive ions of said gas in the path of said beam which act to keep the beam electrons in a narrow beam as they are accelerated.
  • Apparatus according to claim 4 including pulsing means for actuating said means for effecting an emission of electrons as the accelerating field is first being established by said energizing means and prior to the breakdown of said gas by said accelerating field.
  • said means for effecting an emission of electrons in a narrow beam includes a cold emission cathode having a sharp tip disposed within said housing, means for effecting high field emission of electrons from said tip, and beam focusing means for focusing at least a portion of the electrons emitted from said tip into a narrow beam.

Description

Aug. 30, 1966 D. w. KERST 3,270,243
. APPARATUS FOR THE ESTABLISHMENT AND ACCELERATION OF A NARROW HIGH CURRENT BEAM Filed March 21, 1961 United States Patent APPARATUS FOR THE ESTABLISHMENT AND AC- CELERATION OF A NARROW HIGH CURRENT BEAM Donald W. Kerst, San Diego, Calif., assignor to General Dynamics Corporation, New York, N.Y., a corporation of Delaware Filed Mar. 21, 1961, Ser. No. 97,232 6 Claims. (Cl. 315-15) This invention relates to the establishment and acceleration of a beam of particles and more particularly to methods of and apparatus for providing and accelerating an intense narrow beam of electrons.
The establishment and acceleration of intense narrow beams of charged particles, such as electrons, has in the past proven difficult and, under certain conditions, impossible. Efforts to produce such beams have been hampered because high intensity sources of electrons have not been available. Moreover, the acceleration of a narrow beam of high electron intensity has not been feasible because of instabilities due to space charge effects (i.e., intrinsic repulsive forces between beam electrons) and the like.
Accordingly, it is a prime object of the present invention to provide a method of and apparatus for establishing and accelerating an intense narrow beam of electrons.
Another object of the invention is the provision of a method of establishing and accelerating an intense beam of electrons whereby adverse space charge effects and the like are substantially eliminated.
A more specific object of the invention resides in a method of establishing a beam of electrons which is neutralized and confined in a narrow configuration during the passage thereof through an accelerating field.
Other objects and advantages of the present invention will become apparent when considered in conjunction with the accompanying drawing wherein the figure is a diagrammatic representation, partially in cross-section, of an apparatus which may be satisfactorily utilized to establish and accelerate a narrow high intensity beam of electrons in accordance with the provisions of this invention.
In general, a preferred method of establishing and accelerating an intense beam of electrons contemplates the emission of an intense cloud of electrons by a cold cathode. Thereafter in accordance with the provisions of this invention, a dense beam is extracted from the cloud of electrons and focused in a narrow beam. The focused beam is subsequently accelerated through a glow discharge plasma containing substantially equal numbers of electrons and positive ions whereby the beam is space charge neutralized and maintained in the narrow configuration.
Referring now in detail to the beam forming and accelerating apparatus illustrated in the figure, a cold emission cathode 9, which is preferably formed of an electron emitting material such as tungsten (wolfram), is suitably mounted within and in spaced relation to the wall of an evacuated accelerating tube that has an ionizable gas supplied thereto from a source 11. The cathode 9 is proportioned with a sharp cone-shaped end section or tip 9a and is suspended within the accelerating tube 10 so that the longitudinal axis thereof is aligned with the longitudinal axis of the tube.
A terminal 12 is secured to the base of the cold emission cathode 9 and is maintained in electrical contact with the grounded wall of the accelerating tube 10 through a resistor 13. Positioned in spaced relation to the cathode 9, the cone-shaped tip of which is directed toward the outlet extremity of the tube 10, is a high voltage electrode 14. A conductor 14a extends from the electrode 14 to a highly negative source of potential 15 through a gas-tight insulating bushing 14b that is mounted in the wall of the tube 10. A trigger probe 16 is disposed between the electrode 14 and the cathode 10. This trigger probe is selectively supplied With potential from a pulsing source 17 through a conductor 16a. The conductor 16a extends through a gas-tight insulating bushing 16b that is also mounted in the wall of the accelerating tube.
The potential difference that exists between the terminal 12 and the negative electrode 14 is insufficient to effect the establishment of an arc discharge between these members. However, the magnitude of this potential difference is sufficient to maintain an arc discharge subsequent to the establishment thereof, which is accomplished by the selective operation of the pulsing source 17. More particularly, the magnitude and duration of the voltage pulse supplied to the trigger probe 16 is sufiicient to initiate a discharge between the probe and the terminal 12. Thereafter, as the pulse is dissipated, the high negative potential on the electrode 14 attracts and effects the transfer of the are from the pro-be 16 to the electrode. With the are established between the terminal 12 and the electrode 14, a complete path for current flow is provided from the source 15 to the grounded wall of the accelerating tube 10 through the resistor 13.
The passage of current through the resistor 13 results in the development of voltage thereacross. Inasmuch as the resistor 13 offers a substantial amount of impedance to this flow of current, the developed voltage is substantially equal in magnitude to the highly negative potential supplied by the source 15. Because the resistor is maintained in electrical contact with the cathode through the terminal 12, the negative potential developed across the resistor is supplied to the tip of the cathode 9.
A plate 18 is positioned in spaced relation to the highly negative cone-shaped tip of the cathode 9. The plate is mounted within the accelerating tube 10 normal to the longitudinal axis thereof and is maintained in electrical contact with the grounded wall of the tube. Consequently, the plate is substantially more positive than the tip 9a of the cathode 9. The unique cone-shaped configuration of the tip 9a coupled with the difference of potential between the cathode and the plate 18 results in the establishment of an intense electrical field which is concentrated at the tip of the cathode. The resulting high potential gradient at the surface of the cathode 9 results in the emission of an extremely high current and intense flow of electrons away from the cone-shaped tip and toward the plate 18.
The electrons emitted from the tip of the cathode are passed through a circular aperture 19 which is formed in the plate 18. The center of radius of the circular aperture 19 lies on a line defined by the longitudinal axis of the gas filled tube and, as illustrated, is spaced in close proximity to the cathode 9. The diameter of the aperture is chosen in accordance with the calculated magnitude of the angle of spread of the electrons being emitted from the cone shaped tip of the cathode. Accordingly, substantially all of the electrons attracted toward the plate 18 pass through the aperture and into a focusing system generally designated by the numeral 21. The function of the focusing system is to optimize or adjust the product of the beam diameter times the angle of spread of the electron paths.
The focusing system 21 includes a pair of electromagnets 22 and 23 that are supplied with power from a suitable source 24. As illustrated, these focusing members are positioned in spaced relation to the plate 18 and in alignment with the aperture formed therein. The electromagnetic focusing accomplished by the members 22 and 23 substantially minimizes the spread of the beam just prior to the transmittal thereof to an accelerating section 26 of the tube 11. Accordingly, the beam advanced into the accelerating section 26 will be substantially confined to a narrow path in the region of the longitudinal axis of the tube. While in the illustrated embodiment, focusing of the beam is accomplished electromagnetically, modifications of the structural features of the focusing system 21 could be readily accomplished so that electrostatic focusing of the electron beam could also be utilized.
As shown in the figure, the accelerating section 26 of the tube 11 includes a plurality of ring-type magnetic cores 27 which are suspended in spaced relation to the wall of the tube and generally normal to the longitudinal axis thereof. The center of each of the ring-type magnetic cores lies on the longitudinal axis of the tube, and each has a conductive member 28 wound around the entire surface thereof. The conductive members 28, which are preferably wound in a single layer about the surface of the cores 27, have exciting current supplied thereto from a current source 29. The passage of exciting current through the conductive members results in the establishment of a magnetic field about each of the cores having lines of flux which induce or set up individual axial electric accelerating fields in a direction away from the electromagnetic focusing members 22 and 23 and toward a target 31 which is mounted at the outlet extremity of the tube 10.
The current source 29 also includes a conventional high frequency current generating system which is selectively rendered effective to initiate or tickle a glow discharge in the region adjacent the longitudinal axis of the accelerating tube 10. More particularly, the intermittent passage of high frequency pulses of current through the conductors 28 results in the breaking down and ionization of the gas supplied from the source 11 to the accelerating region of the tube 10. Consequently a glow discharge plasma, which contains substantially equal numbers of electrons and positive ions is established in the region surrounding the longitudinal axis of the tube. As will be hereinafter described, this glow discharge plasma, and more accurately the positive ions of the glow discharge plasma, function to neutralize the beam of electrons transmitted through the accelerating section of the tube subsequent to the focusing thereof by the electromagnets 22 and 23.
The magnitude of both the exciting and ionizing or glow discharge-producing currents is limited so that an arc discharge is not established Within the tube. Consequently, the exciting current, which establishes the individual axial accelerating fields, and the high frequency ionizing current, which is intermittently applied to the conductors 28, coact to effect both the acceleration and neutralization of the electron beam while substantially eliminating the adverse effects which might result from the creation of an arc discharge in the tube. The preionized glow discharge, which can be initiated or tickled in a variety of ways, will not convert into an arc discharge for several microseconds after the main exciting or accelerating field is established. Accordingly, all of the emitted electrons will be accelerated through the glow discharge before any arc discharge is created in the tube.
As illustrated, a plurality of circular plates 33, which are electrically connected to the grounded wall of the tube and mounted generally normal to the longitudinal axis thereof, are spaced along the length of the tube from the inlet of the accelerating section 26 to the outlet of the section adjacent to the target 31. One each of the plates 33 is mounted between each of the ring-type magnetic cores 27 and each has a circular aperture provided therein so that the focused electrons passing through the accelerating section are not obstructed thereby.
Secured to and extending from each of the plates 33 is a cylindrical section 34 which is positioned in spaced and concentric relation to the inner surface of each of the magnetic cores 27. These cylindrical sections 34 have a diameter which is larger than the diameter of the aperture provided in each of the plates 33 but smaller than that of the inner cylindrical surface of the magnetic cores 27.
Extending inwardly from each of the cylindrical sections 34 normal to the longitudinal axis of the tube are a plurality of disc-like bafiie members 35. The inner diameter of each of the disc-like bafile members 35 is substantially equal to the diameter of the aperture provided in the plates 33. The bafile members 35 function to preclude the occurrence of an arc discharge within the tube subsequent to the preionization of the gaseous medium maintained therein. More partciularly, these bathe members limit the distance through which stray electrons can travel and further preclude the establishment of an electron avalanche and the undesirable beam destroying effects that would result from an arc discharge.
A plurality of metallic screen segments 36, which in a preferred embodiment of the invention are cylindrical in shape, is mounted along the longitudinal axis of the tube. The screen segments are preferably positioned in electrical contact with the innermost edge of the disclike baffie members 35 and the aperture defining surfaces of the plates 33. Accordingly, the screen segments, which are concentric with the ring-type magnetic cores 27, define a cylindrical region wherein the positive ions of the glow discharge plasma effect neutralization of the beam of electrons accelerated and transmitted therethrough toward the target 31. As illustrated, the individual screen segments 36 are spaced from each circular plate 33 associated with the following cylindrical section 34. The purpose of this spacing is to provide an eccelcrating gap 34a and to preclude short circuiting of each of the magnetic cores 27.
The target 31 is preferably a thin foil member which is framed across a projecting cylindrical end portion of the accelerating tube 10 normal to the longitudinal axis thereof. The target is made of a material which functions to pass the narrow beam from the accelerator while precluding the scattering thereof. One such material which may be satisfactorily utilized for this application is beryllium. The beam which is formed and accelerated through the tube and which is transmitted therefrom through the target 31 may be utilized in any number of applications where a narrow beam of accelerated particles is required.
A preferred method of establishing and accelerating a high current beam of electrons and transmitting the beam through the beryllium foil target 31 is initiated by ionizing the gaseous medium confined in the region defined by the screen segments 36. As previously described the ionization of the gas is effected by passing a high frequency current of preselected magnitude from the source 29 through each of the conductive members 28 that surround the ring-type magnetic cores 27. Thereafter, the passage of exciting current through the conductive members 28 results in the establishment of an accelerating electric field along the longitudinal axis of the tube.
Subsequently, the selectively operable pulsing source 17 is rendered effective to effect the establishment of an arc discharge between the terminal 12 of the cathode 9 and the electrode 14. The high field established between the tip 9a of the cathode and the plate 18 results in the emission of a high current 'beam of electrons which are advanced through the aperture 19 provided in the attracting plate 18. The electrons emitted from the tip of the cathode, after travelling through the aperture 19, are focused by the electromagnets 22 and 23, and the focused beam is transmitted to the accelerating section 26 of the tube.
When the focused beam enters the accelerating field established by the excited cores 27, the neutralizing glow discharge plasma produced near the longitudinal axis of the tube by the intermittent passage of a high frequency current through the conductor 28 effects neutralization of the beam. More particularly, as the beam is accelerated through the plasma the electrons therein are repulsed and pass through the cylindrical screen segments which are disposed in concentric fashion about the longitudinal axis of the tube. Accordingly, an abundance of positive ions formerly associated with the repulsed plasma electrons remains in the path of the beam and effects neutralization of the beam of electrons. This neutralization accomplished by the positive plasma ions substantially eliminates the intrinsic repulsive forces between beam electrons. Accordingly, as the beam advances through the accelerating field the narrow configuration thereof is maintained until the entire length of the accelerating section 26 has been traversed and the beam is transmitted through a foil target for use in some suitable external application. Additional focusing of the neutralized and accelerated beam by a focusing system similar to the focusing system 21 might be required to preclude the establishment of instabilities within the beam after passing through the target 31.
In the preferred embodiment of the invention, the accelerator tube is approximately 1000 cm. in length and has a diameter of approximately 25 cm. The cold cathode 9 is proportioned so that a plurality of emissions having a duration of l microsecond can be effected prior to the replacement thereof. An ionizable gas which is supplied to the tube from the source 11 is maintained therein at a pressure of approximately 10- mm. or less. Approximately 250 ring-type magnetic cores, which establish an electric accelerating field of approximately 20 kv./cm. within the tube and thereby effect the acceleration of the beam therein, are arranged along the length thereof so that the beam of electrons passing through the tube has approximately 5 mev. of energy imparted thereto. Neutralization of a beam having a radius of approximately 1 mm. and containing 10 to 10 amperes of electrons can be effected by approximately 10 ions per cubic centimeter which are attainable in a moderate preionized glow discharge. These factors as well as the remaining structural features of the tube, for example, the location of the baffle members 35, insure that a beam of 10 to 10 amperes of electrons can be passed through the accelerator for l microsecond without the preionized glow discharge becoming an arc discharge.
It should be clearly understood that the foregoing is merely illustrative of a preferred method of and apparatus for creating a narrow beam of accelerated electrons. Numerous modifications of the contemplated mode and of the apparatus for accomplishing the same could be devised by those skilled in the art without deviating from the spirit and scope of the invention. Various features of the invention are set forth in the accompanying claims.
I claim:
1. Apparatus for providing and accelerating an intense marrow beam of electrons which comprises an elongated closed cylindrical housing having a foil target mounted at one extremity thereof adjacent the longitudinal axis thereof, a cold emission cathode mounted within said housing adjacent the other extremity thereof, said cathode having an elongated cone-shaped tip directed along the longitudinal axis of said housing toward said foil target, beam focusing means positioned within said housing in coaxial relation with the longitudinal axis thereof and in spaced relation to the cone-shaped tip of said cathode, means interposed between said cathode and said focusing means for effecting a high field emission of electrons from the tip of said cathode and for directing the emitted electrons to said beam focusing means, a plurality of spacedapart ring-type cores mounted within said housing in concentric relation with the longitudinal axis thereof, said cores being disposed transversely of the longitudinal axis of said housing and spaced between said focusing means and said foil target, and means for selectively energizing said cores so as to establish a glow discharge within said housing adjacent the longitudinal axis thereof and create an accelerating field in the direction of the outlet extremity of said housing, said glow discharge functioning to neutralize the focused beam of electrons emanating from said focusing means and being accelerated toward said target along the longitudinal axis of said housing so that the beam of electrons is maintained in a narrow configuration.
2. Apparatus for providing and accelerating an intense narrow beam of electrons which comprises an elongated closed cylindrical housing having a foil target mounted at one extremity thereof adjacent the longitudinal axis thereof, a cold emission cathode mounted within said housing adjacent the other extremity thereof, said cathode having an elongated cone-shaped tip directed along the longitudinal axis of said housing toward said foil target,
beam focusing means positioned within said housing in coaxial relation with the longitudinal axis thereof and in spaced relation to the cone-shaped tip of said cathode, a plate mounted within said housing in electrical contact therewith between said cathode and said focusing means, said plate having an aperture formed therein adjacent the longitudinal axis of said housing, means for establishing a high negative potential on said cathode relative to said plate, the substantial difference in potential between the tip of said cathode and said plate effecting a high field emission of electrons from the tip of said cathode toward said beam focusing means, a plurality of spaced-apart ringtype magnetic cores mounted within said housing in concentric relation with the longitudinal axis thereof, said magnetic cores being disposed transversely of the longitudinal axis of said housing and spaced between said focusing means and said foil target, and means for selectively energizing said magnetic cores so as to establish a glow discharge within said housing adjacent the longitudinal axis thereof and create an accelerating field in the direction of the outlet extremity of said housing, said glow discharge functioning to neutralize the focused beam of electrons emanating from said focusing means and being accelerated toward said target along the longitudinal axis of said housing so that the beam of electrons is maintained in a narrow configuration.
3. Apparatus for providing and accelerating an intense narrow beam of electrons, which apparatus comprises an elongated housing having a target mounted at one extremity and along the longitudinal axis thereof, a cathode mounted Within said housing adjacent the other extremity thereof, said cathode having an elongated cone-shaped tip directed along the longitudinal axis of said housing and toward said target, beam focusing means positioned wrthm said housing in coaxial relation with the longitudinal axis thereof and in spaced relation to the coneshaped tip of said cathode, means interposed between said cathode and said beam focusing means for effecting a high field emission of electrons from the tip of said cathode and for directing the emitted electrons into said beam focusing means, beam neutralizing means mounted within sald housing between said beam focusing means and said target, and means for selectively energizing said beam neutralizing means so as to establish a glow discharge within said housing adjacent the longitudinal axis thereof and create an accelerating field in the direction of said target, said glow discharge functioning to neutralize the focused beam of electrons emanating from said focusing means and being accelerated toward said target along the longitudinal axis of said housing so that the beam of electrons is maintained in a narrow configuration.
4. Apparatus for accelerating electrons in an intense narrow beam which apparatus comprises a housing, means for supplying gas to the interior of said housing, means for lOIllZlIlg a portion of said gas within said housing, means for effecting an emission of electrons in a narrow beam directed into said gas ionized by said means for lonlzrng, and energizing means operable subsequent to said means for ionizing, said energizing means being operable to establish an electron accelerating field within said ionized gas in the path of said narrow beam of electrons to accelerate the electrons in said beam, said electrons produced by the ionizing of said gas being repelled out of the path of said beam by electrons in said beam, leaving unrepulsed positive ions of said gas in the path of said beam which act to keep the beam electrons in a narrow beam as they are accelerated.
5. Apparatus according to claim 4 including pulsing means for actuating said means for effecting an emission of electrons as the accelerating field is first being established by said energizing means and prior to the breakdown of said gas by said accelerating field.
6. Apparatus according to claim 4 wherein said means for effecting an emission of electrons in a narrow beam includes a cold emission cathode having a sharp tip disposed within said housing, means for effecting high field emission of electrons from said tip, and beam focusing means for focusing at least a portion of the electrons emitted from said tip into a narrow beam.
References Cited by the Examiner UNITED STATES PATENTS 3,036,233 5/1962 Petrie et a1 3l363 X 3,052,088 9/1962 Davis et al 3l363 X 3,099,768 7/1963 Anderson 313-39 X DAVID J. GALVIN, Primary Examiner.
GEORGE WESTBY, RALPH G. NILSON, Examiners.
C. R. CAMPBELL, Assistant Examiner.

Claims (1)

1. APPARATUS FOR PROVIDING AND ACCELERATING AN INTENSE NARROW BEAM OF ELECTRONS WHICH COMPRISES AN ELONGATED CLOSED CYLINDRICAL HOUSING HAVING A FOIL TARGET MOUNTED AT ONE EXTREMITY THEREOF ADJACENT THE LONGITUDINAL AXIS THEREOF, A COLD EMISSION CATHODE MOUNTED WITHIN SAID HOUSING ADJACENT THE OTHER EXTREMITY THEREOF, SAID CATHODE HAVING AN ELONGATED CONE-SHAPED TIP DIRECTED ALONG THE LONGITUDINAL AXIS OF SAID HOUSING TOWARD SAID FOIL TARGET, BEAM FOCUSING MEANS POSITIONED WITHIN SAID HOUSING IN COAXIAL RELATION WITH THE LONGITUDINAL AXIS THEREOF AND IN SPACED RELATION TO THE CONE-SHAPED TIP OF SAID CATHODE, MEANS INTERPOSED BETWEEN SAID CATHODE AND SAID FOCUSING MEANS FOR EFFECTING A HIGH FIELD EMISSION OF ELECTRONS FROM THE TIP OF SAID CATHODE AND FOR DIRECTING THE EMITTED ELECTRONS TO SAID BEAMS FOCUSING MEANS, A PLURALITY OF SPACEDAPART RING-TYPE CORES MOUNTED WITHIN SAID HOUSING IN CONCENTRIC RELATION WITH THE LONGITUDINAL AXIS THEREOF, SAID CORES BEING DISPOSED TRANSVERSELY OF THE LONGITUDINAL AXIS OF SAID HOUSING AND SPACED BETWEEN SAID FOCUSING MEANS AND SAID FOIL TARGET, AND MEANS FOR SELECTIVELY ENERGIZING SAID CORES SO AS TO ESTABLISH A GLOW DISCHARGE WITHIN SAID HOUSING ADJACENT THE LONGITUDINAL AXIS THEREOF AND CREATE AN ACCELERATING FIELD IN THE DIRECTION OF THE OUTLET EXTREMITY OF SAID HOUSING, SAID GLOW DISCHARGE FUNCTIONING TO NEUTRALIZE THE FOCUSED BEAM OF ELECTRONS EMANATING FROM SAID FOCUSING MEANS AND BEING ACCELERATED TOWARD SAID TARGET ALONG THE LONGITUDINAL AXIS OF SAID HOUSING SO THAT THE BEAM OF ELECTRONS IS MAINTAINED IN A NARROW CONFIGURATION.
US97232A 1961-03-21 1961-03-21 Apparatus for the establishment and acceleration of a narrow high current beam Expired - Lifetime US3270243A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US97232A US3270243A (en) 1961-03-21 1961-03-21 Apparatus for the establishment and acceleration of a narrow high current beam

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US97232A US3270243A (en) 1961-03-21 1961-03-21 Apparatus for the establishment and acceleration of a narrow high current beam

Publications (1)

Publication Number Publication Date
US3270243A true US3270243A (en) 1966-08-30

Family

ID=22262307

Family Applications (1)

Application Number Title Priority Date Filing Date
US97232A Expired - Lifetime US3270243A (en) 1961-03-21 1961-03-21 Apparatus for the establishment and acceleration of a narrow high current beam

Country Status (1)

Country Link
US (1) US3270243A (en)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3330901A (en) * 1964-03-25 1967-07-11 Lokomotivbau Elektrotech Electron bombardment melting furnace
US3489944A (en) * 1966-05-27 1970-01-13 Ion Physics Corp High power field emission microwave tube having a cathode delivering nanosecond relativistic electron beams
US3510713A (en) * 1966-07-19 1970-05-05 Willard H Bennett Method of and appparatus for producing a highly concentrated beam of electrons
US3621327A (en) * 1969-12-29 1971-11-16 Ford Motor Co Method of controlling the intensity of an electron beam
US4084095A (en) * 1977-02-14 1978-04-11 Burroughs Corporation Electron beam column generator for the fabrication of semiconductor devices
US4749910A (en) * 1985-05-28 1988-06-07 Rikagaku Kenkyusho Electron beam-excited ion beam source

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3036233A (en) * 1958-11-11 1962-05-22 Vickers Electrical Co Ltd Charged particle accelerators
US3052088A (en) * 1960-06-30 1962-09-04 United Aircraft Corp Particle propulsion device
US3099768A (en) * 1959-03-25 1963-07-30 Gen Electric Low noise electron beam plasma amplifier

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3036233A (en) * 1958-11-11 1962-05-22 Vickers Electrical Co Ltd Charged particle accelerators
US3099768A (en) * 1959-03-25 1963-07-30 Gen Electric Low noise electron beam plasma amplifier
US3052088A (en) * 1960-06-30 1962-09-04 United Aircraft Corp Particle propulsion device

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3330901A (en) * 1964-03-25 1967-07-11 Lokomotivbau Elektrotech Electron bombardment melting furnace
US3489944A (en) * 1966-05-27 1970-01-13 Ion Physics Corp High power field emission microwave tube having a cathode delivering nanosecond relativistic electron beams
US3510713A (en) * 1966-07-19 1970-05-05 Willard H Bennett Method of and appparatus for producing a highly concentrated beam of electrons
US3621327A (en) * 1969-12-29 1971-11-16 Ford Motor Co Method of controlling the intensity of an electron beam
US4084095A (en) * 1977-02-14 1978-04-11 Burroughs Corporation Electron beam column generator for the fabrication of semiconductor devices
US4749910A (en) * 1985-05-28 1988-06-07 Rikagaku Kenkyusho Electron beam-excited ion beam source

Similar Documents

Publication Publication Date Title
US2305884A (en) Electron beam concentrating system
US5537005A (en) High-current, low-pressure plasma-cathode electron gun
US2892114A (en) Continuous plasma generator
JPS6132508B2 (en)
Gushenets et al. Electrostatic plasma lens focusing of an intense electron beam in an electron source with a vacuum arc plasma cathode
Septier Production of ion beams of high intensity
US20040146133A1 (en) Ultra-short ion and neutron pulse production
US7579578B2 (en) Advanced multipurpose pseudospark switch having a hollow cathode with a planar spiral electrode and an aperture
JPS63503022A (en) plasma anode electron gun
US3271556A (en) Atmospheric charged particle beam welding
US3270243A (en) Apparatus for the establishment and acceleration of a narrow high current beam
US2883580A (en) Pulsed ion source
US2499289A (en) Ion generator
US2785311A (en) Low voltage ion source
US3025429A (en) Ion magnetron
US2901628A (en) Ion source
US3376469A (en) Positive ion-source having electron retaining means
JPH07169425A (en) Ion source
RU2581618C1 (en) Method of generating beams of fast electrons in gas-filled space and device therefor (versions)
US3610989A (en) Production and utilization of high-density plasma
Devyatkov et al. Generation of high-current low-energy electron beams in systems with plasma emitters
CA1260161A (en) Axial flow plasma shutter
Gushenets et al. Effect of the enhanced breakdown strength in plasma-filled optical system of electron beam formation
Mesyats et al. Runaway electron flows in magnetized coaxial gas diodes
US5694005A (en) Plasma-and-magnetic field-assisted, high-power microwave source and method

Legal Events

Date Code Title Description
AS Assignment

Owner name: GA TECHNOLOGIES INC 10955 JOHN JAY HOPKINS DR. P.

Free format text: ASSIGNS ENTIRE INTEREST. SUBJECT TO REORGANIZATION AGREEMENT DATED JUNE 14, 1982;ASSIGNOR:GENERAL ATOMIC COMPANY;REEL/FRAME:004081/0313

Effective date: 19821029