Abstract: A nanoelectromechanical (NEM) device and a method of making same employ a laterally extending nanowire. The nanowire is grown in place from a vertical side of a vertically extending support block that is provided on a horizontal surface of a substrate. The nanowire is spaced from the horizontal surface. The NEM device includes a component that is provided to influence the nanowire.

Abstract: A system and method for developing a solid state stripper device is described that more effectively strips off negative carbon ions to produce positively charged carbon ions. In one embodiment the solid state stripping device is a self-supporting aggregate of nanotubes or Buckminster-Fullerenes. Such devices provide, among other things, carbon stripper foil for use in a tandem generator.

Abstract: An ion source and a polishing system using the ion source are disclosed. The ion source includes a discharge chamber, an electron emitter, a cathode, a screen grid, an accelerator grid, and a screen electrode. The discharge chamber is configured for accommodating discharge gas. The electron emitter is disposed in the discharge chamber. The cathode, the screen grid, the accelerator grid, and the accelerator grid are separately aligned in the discharge chamber in an ascending order with respect to the respective distance thereof from the electron emitter. The electron emitter, the cathode, the screen grid, the accelerator grid, and the accelerator grid are powered in order of descending voltages. The screen electrode defines an adjustable orifice to permit adjustment of an ion-beam ejecting area associated with the orifice. The polishing system further employs a movable stage and control and monitor components, in addition to the ion source.

Abstract: An ion beam apparatus includes a plasma chamber with a grid assembly installed at one end of the plasma chamber and a plasma sheath controller disposed between the plasma chamber and the grid assembly. The grid assembly includes first ion extraction apertures. The plasma sheath controller includes second ion extraction apertures smaller than the first ion extraction apertures. When the plasma sheath controller is used in this configuration, the surface of the plasma takes on a more planar configuration adjacent the controller so that ions, extracted from the plasma in a perpendicular direction to the plasma surface, pass cleanly through the apertures of the grid assembly rather than collide with the sidewalls of the grid assembly apertures. A semiconductor manufacturing apparatus and method for forming an ion beam are also provided.

Abstract: An image display apparatus for forming an image in an image displaying region provided with a vacuum chamber having an electron source substrate and an image forming substrate has an ion pump for evacuating the vacuum chamber by an action of a magnet-filed-forming portion through an aperture portion formed in the electron source substrate or an image displaying substrate, wherein the magnet-filed-forming portion is arranged so that a shadow formed by perpendicularly projecting the magnet-filed-forming portion onto the electron source substrate or the image forming substrate can be located outside the image displaying region.

Abstract: This invention features a combined radio frequency (RF) and Hall Effect ion source and plasma accelerator system including a plasma accelerator having an anode and a discharge zone, the plasma accelerator for providing plasma discharge. A gas distributor introduces a gas into the plasma accelerator. A cathode emits electrons attracted to the anode for ionizing the gas and neutralizing ion flux emitted from the plasma accelerator. An electrical circuit coupled between the anode and the cathode having a DC power source provides DC voltage. A magnetic circuit structure including a magnetic field source establishes a transverse magnetic field in the plasma accelerator that creates an impedance to the flow of the electrons toward the anode to enhance ionization of the gas to create plasma and which in combination with the electric circuit establishes an axial electric field in the plasma accelerator.

Abstract: In certain example embodiments of this invention, there is provided an ion source including an anode and a cathode. In certain example embodiments, a multi-piece outer cathode is provided. The multi-piece outer cathode allows precision adjustments to be made, thereby permitting adjustment of the magnetic gap between the inner and outer cathodes. This allows improved performance to be realized, and/or prolonged operating life of certain components. This may also permit multiple types of gap adjustment to be performed with different sized outer cathode end pieces. In certain example embodiments, cathode fabrication costs may also be reduced.

Abstract: A closed drift ion source is disclosed. The ion source has an open end 1 and a central axis 150 around which are arranged outer magnetic pole piece 3, inner magnetic pole piece 5, anode 2, shield 6 and back magnetic shunt 17. In one embodiment the anode 2 and inner magnetic pole piece 5 are annular. Permanent magnets 7 are located behind the shield 6 and in contact with outer magnetic pole piece 3 and the back magnetic shunt 17. As a result the magnetic field lines pass through the magnetic pole pieces and a mirror magnetic field is set up in the discharge region between them. The inner magnetic pole piece 5 is hollow which facilitates production of the mirror magnetic field.

Abstract: A system for joining at least two beams of charged particles that includes directing a first beam along a first axis into a field. A second beam is directed along a second axis into the field. The first and second beams are turned, by interaction between the field and the first and second beams, into a third beam directed along a third axis.

Abstract: Disclosed is a high-frequency discharge plasma generation-based two-stage Hall-effect plasma accelerator, which comprises an annular acceleration channel having a gas inlet port, a high-frequency wave supply section, an anode, a cathode, a neutralizing electron generation portion and a magnetic-field generation element, wherein: gas introduced from the gas inlet port into the annular acceleration channel is ionized by a high-frequency wave supplied from the high-frequency wave supply section, to generate plasma; a positive ion includes in the generated plasma is accelerated by an acceleration voltage applied between the anode and cathode, and ejected outside; and an electron included in the generated plasma is restricted in its movement in the axial direction of the annular acceleration channel by an interaction with a magnetic field.

Abstract: An ion doping system includes a chamber 11, an exhausting section 13 for exhausting gases from the chamber, an ion source 12 provided for the chamber, and an accelerating section 23 for extracting the ions, generated in the ion source 12, from the ion source 12 and accelerating the ions toward a target. The ion source 12 includes an inlet port 14 to introduce a gas including a dopant element, a filament 15 emitting thermo electrons, and an anode electrode 17 to produce an arc discharge between the filament and itself. The ion source 12 decomposes the gas through the arc discharge, thereby generating ions including the dopant element. The ion doping system controls the arc discharge such that a constant amount of arc current flows between the filament and the anode electrode.

Abstract: The present invention provides an electron optical lens column suitable for miniaturization, and provides the manufacturing method thereof. The column unit (1) comprises an inner column (11) and an outer column (12). The column unit is, as a whole, structured from a high-resistance electrically conductive ceramic. Electrostatic lenses (21, 22, 23, and 24) are affixed to the inner surface (111) of the inner column using a means such as plating or vapor deposition. Of the electrodes or electrode parts (211–213, 221, 231, 232, and 241–243) from which the lens is structured, those that share the same electric potential are connected by shared interconnections. This makes it possible to connect all of the electrodes or electrode parts with shared electric potentials as a group to the external interconnections.

Abstract: A filament for generating electrons for an electron beam emitter where the filament has a cross section and a length. The cross section of the filament is varied along the length for producing a desired electron generation profile.

Abstract: An efficiency enhancing anode-magnetic structure of a Hall effect thruster produces a radially directed magnetic field between inner and outer poles at the exit portion of a gas distribution channel. The field-shaping structure includes magnetic material extending alongside the channel with an associated secondary flux-generating component to create an axially directed magnetic field in the area between the anode of the thruster and the exit portion of the gas distribution channel.

Abstract: There is described, for example, a generally cylindrical generator of energetic electrons that releases electrons from a vacuum enclosure into a surrounding space including into the atmosphere where the electrons may be used for a variety of applications including clean up of a flowing gas stream. Described is an efficient electron generator that emits more beam power than past structures in this class of devices and does so in connection with the treatment of gases or surfaces requiring treatment.

Abstract: A Hall-type ion source for generation of ion beams for technological applications presents itself a hybrid ion source, where properties of closed drift systems and end-Hall ion sources are combined for more efficient operation. An ion source has shorter central magnetic pole than regular closed drift ion source with magnetic screens that provide positive magnetic gradient in an ion source's discharge channel. An ion source with these combined properties has higher ratio of ion beam current to discharge current than end-Hall ion source and wider range of discharge parameters than closed drift ion source.

Abstract: A system for joining at least two beams of charged particles that includes directing a first beam along a first axis into a field. A second beam is directed along a second axis into the field. The first and second beams are turned, by interaction between the field and the first and second beams, into a third beam directed along a third axis.

Abstract: A multi-grid ion beam source has an extraction grid, an acceleration grid, a focus grid, and a shield grid to produce a highly collimated ion beam. A five grid ion beam source is also disclosed having two shield grids. The extraction grid has a high positive potential and covers a plasma chamber containing plasma. The acceleration grid has a non-positive potential. The focus grid is positioned between the acceleration grid and the shield grid. The combination of the extraction grid and the acceleration grid extracts ions from the plasma. The focus grid acts to change momentum of the ions exiting the acceleration grid, focusing the ions into a more collimated ion beam than previous approaches. In one embodiment, the focus grid has a large positive potential. In another embodiment, the focus grid has a large negative potential.

Abstract: An electron beam gun comprises a beam waveguide and an accelerating anode fixed thereto. The accelerating anode is connected with the aid of high-voltage insulators and through a cathode plate to a cathode assembly. The cathode assembly comprises a linear hot cathode fixed with the aid of two cathode carriers and a focussing electrode which is coaxially arranged with respect to the linear hot cathode and encompasses it with the aid of a two-sided surface. The beam waveguide is separated from the accelerating anode with the aid of rack panels which rigidly fix the accelerating anode to the beam waveguide in such a way that a space is formed therebetween. In order to hermetically separate cathode and anode parts of the projector, the accelerating anode is provided with a plate rigidly connected thereto.

Abstract: A charged particle apparatus, with multiple electrically conducting semispheric grid electrodes, the grid electrodes mounted in a dielectric mounting ring, with hidden areas or regions to maintain electrical isolation between the grid electrodes as sputter deposits form on the grid electrodes and mounting ring. The grid electrodes are mounted to the mounting ring with slots and fastening pins that allow sliding thermal expansion and contraction between the grid electrodes and mounting ring while substantially maintaining alignment of grid openings and spacing between the grid electrodes. Asymmetric fastening pins facilitate the sliding thermal expansion while restraining the grid electrodes. Electrical contactors supply and maintain electrical potentials of the grid electrodes with spring loaded sliding contacts, without substantially affecting the thermal characteristics of the grid electrodes.

Abstract: An efficiency enhancing anode-magnetic structure of a Hall effect thruster produces a radially directed magnetic field between inner and outer poles at the exit portion of a gas distribution channel. The field-shaping structure includes magnetic material extending alongside the channel with an associated secondary flux-generating component to create an axially directed magnetic field in the area between the anode of the thruster and the exit portion of the gas distribution channel.

Abstract: A system for joining at least two beams of charged particles that includes directing a first beam along a first axis into a field. A second beam is directed along a second axis into the field. The first and second beams are turned, by interaction between the field and the first and second beams, into a third beam directed along a third axis.

Abstract: A drift tube linear accelerator (linac) that can be used for the acceleration of low energy ion beams. The particles enter the linac at low energy and are accelerated and focused along a straight line in a plurality of resonant accelerating structures interposed by coupling structures up to the desired energy. In the accelerating structures, excited by an H-type resonant electromagnetic field, a plurality of accelerating gaps is provided between drift tubes supported by stems, for instance alternatively horizontally and vertically disposed. A basic module composed of two accelerating structures and an interposed coupling structure, or a modified coupling structure connected to a RF power generator, is if necessary linked to a vacuum system and equipped with one or more quadrupoles.

Abstract: An electron accelerator for generating an electron beam includes a vacuum chamber having an outer perimeter and an electron beam exit window. The exit window has a central region and a first end region. An electron generator is positioned within the vacuum chamber for generating electrons. The electron generator and the vacuum chamber are shaped and positioned relative to each other to accelerate the electrons in an electron beam out through the exit window. The electrons pass through the central region of the exit window substantially perpendicular to the exit window and through the first end region of the exit window angled outwardly relative to the exit window. At least a portion of the outwardly angled electrons are directed beyond the perimeter of the electron accelerator.

Abstract: A closed loop exit hole is formed in a magnetically permeable end wall (2) of an enclosure (1) of a closed electron drift ion source. Parts of this end wall separated by the exit hole serve as pole pieces (7 and 8) of the magnetic system and define the first pole gap. The magnetic system includes pole pieces (9 and 10), which define the second pole gap made in the form of a closed loop exit hole and arranged along the direction of ion emission. Magnetomotive force sources (5 and 6) are located in space between two groups of magnetic terminals. The ratio of width of each pole gap and distance between pole pieces of the first (7 and 8) and second (9 and 10) magnetic gaps along the direction of ion emission is not less than 0.05. The invention allows the intensity of the generated ion beam and the energy of ions to be increased, and this is provided by the homogeneous distribution of ion current density across the ion beam section.

Abstract: A system for joining at least two beams of charged particles that includes directing a first beam along a first axis into a field. A second beam is directed along a second axis into the field. The first and second beams are turned, by interaction between the field and the first and second beams, into a third beam directed along a third axis.

Abstract: A charged particle apparatus, with multiple electrically conducting semispheric grid electrodes, the grid electrodes mounted in a dielectric mounting ring, with hidden areas or regions to maintain electrical isolation between the grid electrodes as sputter deposits form on the grid electrodes and mounting ring. The grid electrodes are mounted to the mounting ring with slots and fastening pins that allow sliding thermal expansion and contraction between the grid electrodes and mounting ring while substantially maintaining alignment of grid openings and spacing between the grid electrodes. Asymmetric fastening pins facilitate the sliding thermal expansion while restraining the grid electrodes. Electrical contactors supply and maintain electrical potentials of the grid electrodes with spring loaded sliding contacts, without substantially affecting the thermal characteristics of the grid electrodes.

Abstract: A system for joining at least two beams of charged particles that includes directing a first beam along a first axis into a field. A second beam is directed along a second axis into the field. The first and second beams are turned, by interaction between the field and the first and second beams, into a third beam directed along a third axis.

Abstract: A filament for generating electrons for an electron beam emitter where the filament has a cross section and a length. The cross section of the filament is varied along the length for producing a desired electron generation profile.

Abstract: An apparatus and method for thrusting plasma, utilizing a Hall thruster with segmented electrodes along the channel, which make the acceleration region as localized as possible. Also disclosed are methods of arranging the electrodes so as to minimize erosion and arcing. Also disclosed are methods of arranging the electrodes so as to produce a substantial reduction in plume divergence. The use of electrodes made of emissive material will reduce the radial potential drop within the channel, further decreasing the plume divergence. Also disclosed is a method of arranging and powering these electrodes so as to provide variable mode operation.

Abstract: The present invention concerns a method of tuning a plurality of electrostatic quadrupoles used for focusing an ion beam implanter. The steps of the method include: classifying the plurality of electrostatic quadrupoles into one of a predetermined number of groups, and for each of the predetermined number of groups, tuning the quadrupoles in the group by iteratively substituting values for a voltage ton be applied to each of the quadrupoles in the group using a multi-variable heuristic algorithm and concurrently measuring final beam current measured downstream of the ion accelerator to determine a set of applied voltage values that maximize the final beam current among those applied voltage values tested and utilizing the set of applied voltage values to tune the quadrupoles in the group. If the resulting ion beam is suitable, utilizing the determined applied voltages to tune the quadrupoles.

Abstract: A multi-grid ion beam source has an extraction grid, an acceleration grid, a focus grid, and a shield grid to produce a highly collimated ion beam. A five grid ion beam source is also disclosed having two shield grids. The extraction grid has a high positive potential and covers a plasma chamber containing plasma. The acceleration grid has a non-positive potential. The focus grid is positioned between the acceleration grid and the shield grid. The combination of the extraction grid and the acceleration grid extracts ions from the plasma. The focus grid acts to change momentum of the ions exiting the acceleration grid, focusing the ions into a more collimated ion beam than previous approaches. In one embodiment, the focus grid has a large positive potential. In another embodiment, the focus grid has a large negative potential.

Abstract: In accordance with one specific embodiment of the present invention, a Hall-current ion source of the end-Hall type has an anode that is contoured with one or more recesses in the electron-collecting surface which have areas that are protected from the deposition of externally generated contamination thereon, as well as one or more protrusions that have higher temperatures than the bulk of the anode, thereby increasing the removal or passivation of coatings during operation by the thermal degradation of the coating and the effects of thermomechanical stresses. In another specific embodiment, which can be combined with the above embodiment, electrically isolated baffle or baffles are located to protect a substantial fraction of the electron-collecting surface of the anode from the deposition of externally generated contamination thereon.

Abstract: This ion source includes a chamber having an internal wall surface and an external wall surface, and also includes a cathode, which is provided to be insulated from the chamber, capable of emitting thermal electrons into the chamber, and has a cathode cap protruding into the chamber from an external side of an opening part which is formed to pass through from the external wall surface to the internal wall surface of the chamber and a filament disposed inside the cathode cap, the cathode cap and/or the filament being an alloy containing tungsten (W) as a major component and a predetermined metal element as a minor component.

Abstract: An RF loaded line type CCP source having two collar type electrodes with an operating tube passing through these electrodes. One of the electrodes (high voltage electrode) is connected with the core of a feeding coaxial cable leading to a power supply, and another one is grounded by connection to a braid of the feeding coaxial cable, and the grounded electrode is further extended to form an outer cylindrical shield enveloping the operating tube with the high voltage electrode to provide a termination of an RF loaded line wherein the high voltage electrode with a plasma beam excited within the operating tube by action of an electric field between the electrodes form a core of this RF line. To provide effective contribution of RF energy in the plasma beam, the impedance of this line can be matched to the impedance of the plasma beam and matched also to the impedance of the feeding cable.

Abstract: The invention pertains to the use of enhanced electron emitting surfaces to increase the supply of electrons in a thin film deposition system including the ion source in order to enhance the deposition rates of thin film materials. The use of enhanced electron emitting surfaces reduces the erosion of component parts in the ion source while increasing the rate and quality of the film deposited on the substrate. Allowing for ion source operation at lower gas pressure also increases the range of cold-cathode applications and improving operation at all pressures. The cathode section of the ion source is comprised of a reactive material that upon reaction with a reactive gas forms an insulating thin film on the cathode surface that provides an addition source of electrons for the ion beam source. Also, electron emitters located outside of the ion beam source have cathode sections that comprise enhanced electron emitting surfaces to provide electron flow to the ion beam.

Abstract: An ion source for use in ion assisted deposition of films, has an ionization region, a gas supply supplying ionizable gas to the ionization region, a gas excitation system causing ionization of the gas, ion influencing means forming the ions into a current directed at a target, and an ion source controller controlling the ion source so as to intermittently produce the ion current.

Abstract: A linear accelerator with improved efficiency is disclosed. The linear accelerator contains at least one lower beam energy recirculating linear accelerator which is focused along a constant focal length, and at least one higher beam energy recirculating linear accelerator which is focused along a constant focal length, and a full energy recirculating line which received the beam from the higher energy recirculating linear accelerator and reinjects it into the higher energy recirculating linear accelerator, thereby balancing the focusing profile to the beam energy. Better envelope control, focusing, and higher efficiency is observed in linacs according to the present invention.

Abstract: A filament for generating electrons for an electron beam emitter where the filament has a cross section and a length. The cross section of the filament is varied along the length for producing a desired electron generation profile.

Abstract: A system for joining at least two beams of charged particles that includes directing a first beam along a first axis into a field. A second beam is directed along a second axis into the field. The first and second beams are turned, by interaction between the field and the first and second beams, into a third beam directed along a third axis.

Abstract: An electron accelerator for generating an electron beam includes a vacuum chamber having an outer perimeter and an electron beam exit window. The exit window has a central region and a first end region. An electron generator is positioned within the vacuum chamber for generating electrons. The electron generator and the vacuum chamber are shaped and positioned relative to each other to accelerate the electrons in an electron beam out through the exit window. The electrons pass through the central region of the exit window substantially perpendicular to the exit window and through the first end region of the exit window angled outwardly relative to the exit window. At least a portion of the outwardly angled electrons are directed beyond the perimeter of the electron accelerator.

Abstract: A blanker assembly for an electron beam column obtains synchronicity between the beam blanking signal propagating through its blanker plates and the associated electron beam which is being blanked. Since the blanking signal travels faster than does the electron beam, the desired synchronicity is achieved by use of a dielectric material for propagating the blanking signal to slow down this signal to match the electron beam velocity. By using a dielectric material for high frequency (RF) blanking signals, there will be less signal reflection and greater blanking accuracy because the electron beam is continuously deflected. The blanker plates each include a substance having a relatively low dielectric constant for proipagating the blanking signal between an upper deflection region. The relative slowness of the propagation of the blanking signal between the upper and lower deflection regions provides a delay effect so as to synchronize the blanking signal with the associated electron beam.

Abstract: A system for joining at least two beams of charged particles that includes directing a first beam along a first axis into a field. A second beam is directed along a second axis into the field. The first and second beams are turned, by interaction between the field and the first and second beams, into a third beam directed along a third axis.

Abstract: In accordance with one specific embodiment of the present invention, a Hall-current ion source of the end-Hall type has an anode that is contoured with one or more recesses in the electron-collecting surface which have areas that are protected from the deposition of externally generated contamination thereon, as well as one or more protrusions that have higher temperatures than the bulk of the anode, thereby increasing the removal or passivation of coatings during operation by the thermal degradation of the coating and the effects of thermomechanical stresses.

Abstract: In one embodiment of a compact closed-drift ion source, an ionizable gas is introduced into a annular discharge region. An anode is at one end of this region and an electron-emitting cathode is near the opposite and open end. A magnetic circuit extends from an inner pole piece to an outer pole piece, with both pole pieces near the open end. The electron current in the discharge region interacts with the magnetic field therein to generate and accelerate ions out of the open end. A permeable enclosure surrounds the anode end of the discharge region. Adjacent elements of the permeable enclosure, the inner pole piece, and any intermediate permeable elements are in close proximity, one to the next. A magnetizing means is located only between the outer pole piece and the permeable enclosure.

Abstract: An improved apparatus is provided for in-situ cleaning of electron microscopes and other vacuum chambers. A special RF plasma electrode is housed in a compact cylinder constructed of standard vacuum components and a electrical feedthrough. The device allows oxygen radicals to be generated from air by a low powered RF plasma. The oxygen radical flow by convection into the electron microscope or vacuum chamber to be cleaned and react with hydrocarbons to form CO and H2O vapor which is pumped away.

Abstract: An ion source for use in ion assisted deposition of films, has a ionisation region, a gas supply, supplying ionisable gas to the ionisation region, a gas excitation system causing ionisation of the gas, ion influencing means forming the ions into a current directed at a target, and an ion source controller controlling the ion source so as to intermittently produce the current.

Abstract: An enhanced electron source in most respects similar to a standard cathode assembly for an electron gun includes an electron emitter surrounded by a suppressor electrode, the emitted electrons passing through an extractor electrode. Additionally, the suppressor electrode includes a small ring shaped permanent magnet surrounding the opening in the suppressor electrode through which the emitter tip protrudes. The resulting magnetic field is aligned with the beam axis, and includes a tail which forms a very short focal length magnetic lens immediately following the emitter tip. This magnetic field collimates the electron beam before it enters the downstream electrostatic gun lens, thus increasing the effective angular intensity of the cathode assembly. The aberrations of this collimating lens are very low so that its useful brightness is not reduced. Also the influence of guns lens aberrations is reduced because a smaller aperture angle in the gun lens may be used to obtain higher beam current.

Abstract: According to a known projection lithography method an object is imaged on an imaging surface by means of a telescopic system of rotationally symmetrical electron lenses. The throughput during the production of integrated circuits by means of projection lithography is determined by the amount of current in the imaging electron beam; this current is limited by the resolution-limiting interaction of the electrons (Coulomb interaction). The invention allows for a larger beam current in that areas with a high current concentration are avoided. To this end, the imaging system includes five mutually perpendicular quadrupoles, so that the electrons are concentrated in line-shaped focal spots instead of a (small) circular cross-over. The system is telescopic and the imaging is stigmatic with equal magnifications in the x-z plane and the y-z plane.

Abstract: A low energy ion gun for ion beam processing. The ion gun includes a plasma chamber having an open ended, conductive, non-magnetic body, a first end of which is closed by a flat or minimally dished dielectric member and with electrodes at a second end thereof opposite the first end. The ion gun also has primary magnets arranged around the body for trapping electrons adjacent the wall of the plasma chamber in use of the ion gun and an r.f. induction device. The electrodes include multi-aperture grids arranged for connection to respective positive potential sources and positioned to contact the plasma in the plasma chamber. The apertures of the grids are aligned so that particles emerging from an aperture of a first one of the grids are accelerated through corresponding apertures of the other grids in the form of a beamlet. A plurality of beamlets forms a beam.