Abstract: The disclosure includes a glow-discharge lamp including: an elongate casing transparent to illuminating radiation and containing a plasma gas; a device for applying an electric field for maintaining a plasma in the so-called positive column region of the casing, the device including two electrodes forming an anode and a cathode located in the casing at each end thereof; and a radio-frequency or microwave cathode plasma source arranged in the casing in relation to the cathode-forming electrode, such as to generate a high-frequency discharge located on the surface of the electrode in order to generate the plasma. The disclosure also includes a lighting method of such a glow-discharge lamp.

Abstract: The proposed method allows forming cathode arc plasma flows for high quality coatings. The plasma flows are transported in a plasma-optical system by means of a transport magnetic field generated by electromagnetic coils, super-positioning a constant magnetic field and additional variable magnetic fields deflecting the plasma flows from internal surfaces of the system's elements. In a device for implementing the proposed method, an arc power supply is connected to an anode via a coil, surrounding the anode. In a linear embodiment of the system, an electrically conductive tube section inside the anode is connected to one end of the deflection coil. The other end is connected to the positive terminal of power supply. In the system's non-linear embodiment, additional magnetic fields are established using two additional electromagnetic coils, surrounding the anode and a nonlinear part respectively. The method and device allow for a significantly reduction of losses of macroparticle-free plasma.

Abstract: A microwave plasma generating device has a plasma chamber. A microwave generating device is provided outside of the plasma chamber, and the microwaves are coupled into the plasma chamber via a microwave in-coupling device. The microwave in-coupling device has an inner conductor which leads into the plasma chamber through a chamber wall of the plasma chamber, an insulating tube which encloses the inner conductor and separates the inner conductor from an interior of the plasma chamber, and an outer conductor which leads into the plasma chamber through the chamber wall and which is coaxial to the inner conductor. The outer conductor has an outer conductor end in the plasma chamber. The inner and outer conductors form a microwave line, an outlet of microwaves out of the microwave line is provided in the plasma chamber to generate microwave plasma in the interior of the plasma chamber.

Abstract: In accordance with one embodiment of the present invention, an end-Hall ion source has an electron emitting cathode, an anode, a reflector, an internal pole piece, an external pole piece, a magnetically permeable path, and a magnetic-field generating means located in the permeable path between the two pole pieces. The anode and reflector are enclosed without contact by a thermally conductive cup that has internal passages through which a cooling fluid can flow. The closed end of the cup is located between the reflector and the internal pole piece and the opposite end of the cup is in direct contact with the external pole piece, and wherein the cup is made of a material having a low microhardness, such as copper or aluminum.

Abstract: A showerhead electrode assembly for a plasma processing chamber, which includes a showerhead electrode; a heater plate secured to the showerhead electrode; at least one pressure controlled heat pipe secured to an upper surface of the heater plate, the at least one pressure controlled heat pipe having a heat transfer liquid contained therein, and a pressurized gas, which produces a variable internal pressure within the at least one pressure controlled heat pipe; a top plate secured to an upper surface of the at least one heat pipe; and wherein the variable internal pressure within the at least one pressure controlled heat pipe during heating of the showerhead electrode by the heater plate displaces the heat transfer liquid from a thermal path between the top plate and the heater plate, and when removing excess heat from the showerhead electrode returns the heat transfer liquid to the thermal path.

Abstract: The inspection of a sample with VUV light from a laser sustained plasma includes generating pumping illumination including a first selected wavelength, or range of wavelength, containing a volume of gas suitable for plasma generation, generating broadband radiation including a second selected wavelength, or range of wavelengths, by forming a plasma within the volume of gas by focusing the pumping illumination into the volume of gas, illuminating a surface of a sample with the broadband radiation emitted from the plasma via an illumination pathway, collecting illumination from a surface of the sample, focusing the collected illumination onto a detector via a collection pathway to form an image of at least a portion of the surface of the sample and purging the illumination pathway and/or the collection pathway with a selected purge gas.

Abstract: An electromagnetic radiation amplifier (and concomitant amplification method) comprising a pulsed power source, a spherical or half-spherical cathode proximate the power source, an anode focusing assembly comprising a plurality of converger/spreader spheres, and a plurality of current conductors connecting the cathode and the anode focusing assembly.

Abstract: A plasma interaction simulator is presented. The simulator magnetically induces multiple distinct flows of plasma within a physical plasma vessel. The plasma flows collide with each other at flow interaction boundaries where discontinuities arising due to differences between the flows give rise to interactions. Sensors can be incorporated into the plasma simulator to observe and collect data about the plasma flow interactions.

Abstract: A plasma processing apparatus may include a process chamber having an interior processing volume; a first RF coil to couple RF energy into the processing volume; a second RF coil to couple RF energy into the processing volume, the second RF coil disposed coaxially with respect to the first RF coil; and a third RF coil to couple RF energy into the processing volume, the third RF coil disposed coaxially with respect to the first RF coil, wherein when RF current flows through the each of the RF coils, either the RF current flows out-of-phase through at least one of the RF coils with respect to at least another of the RF coils, or the phase of the RF current may be selectively controlled to be in-phase or out-of-phase in at least one of the RF coils with respect to at least another of the RF coils.

Abstract: The present invention relates to a multiple-mode plasma generation apparatus that can supply plasma for multiple processes in order to improve processing efficiency. The plasma generation apparatus may include a first plasma generation unit and a second plasma generation unit connected in series with the first plasma generation unit. Here, a gas is changed to plasma by a magnetic field generated by the first plasma generation unit and the second plasma generation unit, the first plasma generation unit is operated by a low-frequency power supply, and the second plasma generation unit is operated by a high-frequency power supply.

Abstract: Provided is a compact ignition coil apparatus that can realize reliable insulation breakdown and spark discharge with high discharge current. A high-frequency discharge ignition coil apparatus includes: a capacitor 116 connected to a high-voltage terminal, for preventing passage of high voltage; and an inductor 117 connected to the capacitor 116 and forming, together with the capacitor 116, a band pass filter that allows only a predetermined frequency component to pass. High-frequency current is supplied from outside to the inductor 117. The high-frequency discharge ignition coil apparatus further includes a current level detection device 115 for detecting the level of current flowing in the inductor 117. The current level detection device 115 is placed in one package, together with a primary coil 111, a secondary coil 112, a capacitor 116, and an inductor 117.

Abstract: A plasma processing apparatus and method are disclosed which allows switching between the E and H operation modes and also increase the coupling efficiency of the RF power to the plasma. This apparatus may increase plasma density by a factor of about 1.25-1.65 for a given power output. Simultaneously, due to the high efficiency, the need to cool the antenna may be eliminated. A new antenna geometry which increases the amount of surface area for a given volume is used to take advantage of skin effects associated with RF electric current. In some embodiments, the antenna has a single turn to reduce proximity effects. The antenna may also be embedded in a ferrite material to further optimize its performance.

Abstract: A plasma generation device, including: an ionization unit that ionizes gas in a target space; an electromagnetic wave oscillator that oscillates an electromagnetic wave to be radiated to the target space; and an antenna that radiates the electromagnetic wave supplied from the electromagnetic wave oscillator to a gas ionization region in which gas ionized by the ionization unit is provided. The ionization unit ionizes gas and the antenna radiates the electromagnetic wave thereto to generate plasma. A plurality of strong electric field regions are formed around the antenna when the electromagnetic wave is supplied from the electromagnetic wave oscillator. The strong electric field region is a region stronger in electric field than the surrounding area. The ionization unit ionizes gas around the plurality of strong electric field regions, or gas around a plurality of regions in which immediately before strong electric fields come into existence.

Abstract: In some embodiments, the present disclosure relates to a plasma processing system that generates a magnetic field having a maximum strength that is independent of workpiece size. The plasma processing system has a plurality of side electromagnets that have a size which is independent of the workpiece size. The side electromagnets are located around a perimeter of a processing chamber configured to house a semiconductor workpiece. When a current is provided to the side electromagnets, separate magnetic fields emanate from separate positions around the workpiece. The separate magnetic fields contribute to the formation of an overall magnetic field that controls the distribution of plasma within the processing chamber. Because the size of the plurality of separate side magnets is independent of the workpiece size, the plurality of side magnets can generate a magnetic field having a maximum field strength that is independent of workpiece size.

Abstract: Disclosed herein are systems, methods and apparatuses for dissociating a non-activated gas through a disc-shaped plasma in a remote plasma source. Two inductive elements, one on either side of the disc-shaped plasma, generate a magnetic field that induces electric fields that sustain the disc-shaped plasma. The inductive elements can be coiled conductors having any number of loops and can be arranged in planar or vertical coils or a combination of planar and vertical coils. Additionally, the ratio of inductive element radius to gap distance between the two inductive elements can be configured to achieve a desired vertical plasma confinement.

Abstract: A plasma generating apparatus and a substrate processing apparatus are disclosed. The plasma generating apparatus includes a disk-shaped first electrode receiving first RF power of a first frequency to generate plasma, a washer-type second electrode disposed around the circumference of the first electrode and receiving second RF power of a second frequency, an insulating spacer disposed between the first electrode and the second electrode, a first RF power source supplying power to the first electrode, and a second RF power source supplying power to the second electrode.

Abstract: A plasma generating apparatus includes: a power supply one of whose electrodes is connected to vacuum chamber walls of N vacuum chambers; an oscillator which outputs a pulse signal at every predetermined period; N pulse amplifying circuits which are connected in parallel to the oscillator as well as to the other electrode of the power supply, and each of which amplifies the pulse signal and supplies the amplified pulse signal to a corresponding one of N electrodes disposed in the N vacuum chambers; and at least (N-1) timing generating circuits which are connected between the oscillator and at least (N-1) pulse amplifying circuits, and which delay the pulse signal by respectively different delay times so that at any specific time, the pulse signal is supplied to only one of the pulse amplifying circuits.

Abstract: A spheromak is a plasma of ions and electrons formed into a toroidal shape. A spheromak plasma can include electrons and ions of nearly equal amounts such that it is essentially charge neutral. It contains large internal electrical currents and their associated internal magnetic fields arranged so that the forces within the spheromak are nearly balanced. The spheromak described herein is observed to form around an electric arc in partial atmosphere, and is observed to be self-stable with no external magnetic containment.

Abstract: A hybrid plasma reactor includes a first plasma chamber for providing a first ring-shaped plasma discharge space, second plasma chambers providing a second plasma discharge space connected to the first plasma discharge space and coupled to magnetic flux channels, a hybrid plasma source including magnetic cores, which partially surround the first plasma chamber and have magnetic entrances forming the magnetic flux channels, and primary winding coils wound in the magnetic cores and complexly generating ring-shaped transformer-coupled plasma in the first plasma discharge space and magnetic flux channel coupled plasma in the second plasma discharge space, and an AC switching power supply for supplying plasma generation power to the primary winding coils. The hybrid plasma reactor can complexly generate magnetic flux channel coupled plasma and transformer coupled plasma so that it has a high control capability for plasma ion energy and a wide operation region from a low-pressure region to a high-pressure region.

Abstract: Ion-enhanced physical vapor deposition is augmented by sputtering to deposit multi-component materials. The process may be used to deposit coatings and repair material on Ti alloy turbine engine parts. The physical vapor deposition may be ion-enhanced electron beam physical vapor deposition.

Abstract: A magnetron source comprises a target (39) with a sputtering surface and a back surface. A magnet arrangement (30, 32, 19a, 19b) is drivingly moved along the backside of the target (39). A tunnel-shaped magnetron magnetic field is generated between an outer loop (30) and an inner loop (32) of the magnet arrangement. Elongated pivotable or rotatable permanent magnet arrangements (19a, 19b) of the magnet arrangement are provided in an interspace between the outer and inner loops (30, 32) of the overall arrangement.

Abstract: A plasma reactor having multi discharging tubes is disclosed, through which activated gas containing ion, free radical, atom and molecule is generated through plasma discharging, and different process gases are injected into multi discharging tubes in which solid, power and gas, etc., are plasma-treated with the activated gas to perform processes including cleaning process for semiconductor, and a plasma state can be maintained even at low power.

Abstract: An ignition system for a plasma jet ignition plug that enables a reduction in production cost and provides excellent ignition performance through improvement of plasma formation efficiency. The ignition system includes a plasma jet ignition plug having a center electrode, a ground electrode, and a cavity surrounding at least a portion of a gap formed between the center electrode and the ground electrode to form a discharge space, and a voltage application section for applying voltage across the gap. The ignition system further includes a capacitance section having a capacitance and provided in parallel with the plasma jet ignition plug between the plasma jet ignition plug and the voltage application section.

Abstract: To make it easy to adjust a location of an emission antenna in a plasma generation device that generates plasma by a discharge and enlarges the plasma by an electromagnetic wave. A plasma generation device 30 includes an electromagnetic wave generation device 31, an emission antenna 16, a high voltage generation device 14, and a discharge electrode 15. The emission antenna 16 forms a discharge gap together with the discharge electrode 15 which a high voltage outputted from the high voltage generation device 14 is applied to. The plasma generation device 30 enlarges discharge plasma using the electromagnetic wave emitted from the emission antenna 16 caused by the electromagnetic wave outputted from the electromagnetic wave generation device 31, where the discharge plasma is generated at the discharge gap by an output of a high voltage from the high voltage generation device 14.

Abstract: An ion source is provided that includes an ionization chamber and two magnetic field sources. The ionization chamber has a longitudinal axis extending therethrough and includes two opposing chamber walls, each chamber wall being parallel to the longitudinal axis. The two magnetic field sources each comprises (i) a core and (ii) a coil wound substantially around the core. Each magnetic field source is aligned with and adjacent to an external surface of respective one of the opposing chamber walls and oriented substantially parallel to the longitudinal axis. The cores of the magnetic field sources are physically separated and electrically isolated from each other.

Abstract: Plasma-enhanced chemical vapor deposition (PECVD) devices enable the generation of a plasma in a plasma zone of a deposition chamber, which reacts with a surface of a substrate to form a deposited film in the fabrication of a semiconductor component. The plasma generator is often positioned over the center of the substrate, and the generated plasma often remains in the vicinity of the plasma generator, resulting in a thicker deposition near the center than at the edges of the substrate. Tighter process control is achievable by positioning one or more electromagnets in a periphery of the plasma zone and supplying power to generate a magnetic field, thereby inducing the charged plasma to achieve a more consistent distribution within the plasma zone and more uniform deposition on the substrate. Variations in the number, configuration, and powering of the electromagnets enable various redistributive effects on the plasma within the plasma zone.

Abstract: The invention relates to an induction switch comprising a discharge container filled with gas and a coaxially interleaved electrode device, and to a corresponding method for commutating high voltages. The inductive production of a dense plasma and the subsequent flooding of an electrode gap with the plasma ions produced enables the commutation of high currents in the kiloamp range when there are blocking voltages of over 500 kV. Such an induction switch only requires a single discharge gap, can be used over a very wide voltage range, and avoids the problem of electrode erosion as a result of the electrode-free energy coupling.

Abstract: An arrangement for generating plasma, the arrangement comprising a primary plasma source (1) comprising a primary source chamber (15) and a first coil (4) for generating plasma in the primary source chamber, a secondary plasma source (25) comprising a secondary source chamber (16) and a second coil (26) for enhancing plasma generated by the primary plasma source and/or generating plasma in the secondary source chamber generating plasma in the primary source chamber, a hollow guiding body (11) arranged for guiding at least a portion of the plasma generated by the primary plasma source to the secondary plasma source, and an outlet (14) for emitting at least a portion of the plasma generated by the arrangement.

Abstract: A method for generating atmospheric pressure cold plasma inside a hand-held unit discharges cold plasma with simultaneously different rf wavelengths and their harmonics. The unit includes an rf tuning network that is powered by a low-voltage power supply connected to a series of high-voltage coils and capacitors. The rf energy signal is transferred to a primary containment chamber and dispersed through an electrode plate network of various sizes and thicknesses to create multiple frequencies. Helium gas is introduced into the first primary containment chamber, where electron separation is initiated. The energized gas flows into a secondary magnetic compression chamber, where a balanced frequency network grid with capacitance creates the final electron separation, which is inverted magnetically and exits through an orifice with a nozzle. The cold plasma thus generated has been shown to be capable of accelerating a healing process in flesh wounds on animal laboratory specimens.

Abstract: Various embodiments include a device for generating plasma and for directing an flow of electrons towards a specific target; the device comprises a hollow cathode; a main electrode at least partially placed inside the cathode; a resistor, electrically earthing the main electrode; a substantially dielectric tubular element extending through a wall of the cathode; a ring-shaped anode placed around the tubular element and earthed; and an activation group which is electrically connected to the cathode and is able to reduce the electric potential of the cathode of at least 8 kV in about 10 ns.

Abstract: A plasma equipment comprising a microwave oscillator for generating a predetermined microwave band, a microwave resonant cavity for allowing the predetermined microwave band to resonate, and microwave radiation means for radiating the microwave into the microwave resonant cavity, wherein the microwave radiation means is a microwave radiation antenna having the shape and the size so as to form a strong electric field of the microwave in a plasma generation field formed by the microwave.

Abstract: Embodiments of the present application disclose a linear plasma source applied to the field of solar cell production. A linear plasma source comprising a housing which forms a reaction chamber having an outlet; a gas intake system comprising an internal pipeline which is mounted on the housing and located inside the reaction chamber for releasing reaction gas into the reaction chamber; an electrode system comprising at least two electrode plates which are mounted on the housing and located around the internal pipeline within the reaction chamber; and an electromagnetism system comprising an electromagnetic coil, and the electromagnetic coil is mounted at the outlet of the reaction chamber of the housing and has a plasma outlet. The embodiments of the present application have a simple structure, a low production cost, a good uniformity and a high film compactness.

Abstract: A plasma generator having a housing surrounding an ionization chamber, at least one working-fluid supply line leading into the ionization chamber, the ionization chamber having at least one outlet opening, at least one electric coil arrangement which surrounds at least one area of the ionization chamber, the coil arrangement being electrically connected with a high-frequency alternating-current source (AC) which is constructed such that it applies a high-frequency electric alternating current to at least one coil of the coil arrangement, is wherein a further current source (DC) is provided which is constructed such that it applies a direct voltage or an alternating voltage of a frequency lower than that of the voltage supplied by the high-frequency alternating current source (AC) to at least one coil of the coil arrangement.

Abstract: An apparatus for producing EUV light, including: a plate with pluralities of through-bores; at least one power system; and a plurality of discharge plasma devices disposed in the through-bores. Each device includes: a respective plasma electrode forming at least part of a respective plasma-producing region; a respective magnetic core embedded in the plate and aligned with the respective plasma electrode in a radial direction and configured to create a respective magnetic field within the respective plasma-producing region; and a respective feed system arranged to supply an ionizable material to the respective plasma-producing region. The power system is configured to supply electrical power to the plasma electrodes to create respective electric fields in the respective plasma-producing regions. The combination of the respective electric field and the respective magnetic fields is arranged to create respective plasma from the ionizable material, the respective plasma creating respective EUV light.

Abstract: Apparatus and methods for generating and optimizing a plasma discharge are provided. The device includes a plasma generating device, one or more sensors, and at least one controller for adjusting the plasma in light of the sensed characteristics. Methods for optimizing a plasma, particularly a spatially disoriented plasma discharge include generating a plasma, sensing one or more plasma characteristics, modifying one or more plasma generating properties to optimize the plasma.

Abstract: Embodiments of the present invention generally provide a plasma source apparatus, and method of using the same, that is able to generate radicals and/or gas ions in a plasma generation region that is symmetrically positioned around a magnetic core element by use of an electromagnetic energy source. In general, the orientation and shape of the plasma generation region and magnetic core allows for the effective and uniform coupling of the delivered electromagnetic energy to a gas disposed in the plasma generation region. In general, the improved characteristics of the plasma formed in the plasma generation region is able to improve deposition, etching and/or cleaning processes performed on a substrate or a portion of a processing chamber that is disposed downstream of the plasma generation region.

Abstract: Apparatus for forming a magnetic field and methods of use thereof are provided herein. In some embodiments, a plurality of coils having substantially similar dimensions disposed about a process chamber in a symmetric pattern centered about a central axis of the process chamber, wherein the plurality of coils are configured to produce a magnetic field having a plurality of magnetic field lines that are substantially planar and substantially parallel. In some embodiments, the plurality of coils comprises eight coils disposed about the process chamber, wherein each of the eight coils is offset by an angle of about 45 degrees from respective adjacent coils of the eight coils.

Abstract: One embodiment is directed to a plasma source comprising a body in which a cavity is formed and at least two self-contained magnetron assemblies disposed within the cavity. The magnetron assemblies are mutually electrically isolated from each other and from the body. In one implementation of such an embodiment, the self-contained magnetron assemblies comprise closed-drift magnetron assemblies. Other embodiments are disclosed.

Abstract: A method to modulate the density of an electron beam as it is emitted from a cathode, the method comprised of connecting a source of pulsed input power to the input end of a nonlinear transmission line and connecting the output end directly to the cathode of an electron beam diode by a direct electrical connection.

Abstract: A method and apparatus is provided for generating a plasma electron flood using microwave radiation. In one embodiment, a microwave PEF apparatus is configured to generate a magnetic field that rapidly decays over a PEF cavity, resulting in a static magnetic field having a high magnetic field strength near one side (e.g., “bottom”) of the PEF cavity and a low magnetic field strength (e.g., substantially zero) near the opposite side (e.g., “top”) of the PEF comprising an elongated extraction slit. In one particular embodiment, the one or more permanent magnets are located at a position that is spatially opposed to the location of the elongated extraction slit to achieve the rapidly decaying magnetic field. The magnetic field results in an electron cyclotron frequency in a region of the cavity equal to or approximately equal to a microwave radiation frequency so that plasma is generated to diffuse through the extraction apertures.

Abstract: There is provided a plasma generation apparatus capable of forming plasma suitable for a plasma assist method. The plasma generation apparatus includes a chamber 2, a plasma gun 3 arranged so as to face an inside of the chamber 2, and having a cathode 7 for emitting electrons and a convergent coil 11 for forming a magnetic flux to guide the electrons emitted by the cathode 7, and an auxiliary magnet 4 for forming a magnetic flux in the chamber 2, in which an excitation current is applied to the convergent coil 11 so as to vary a direction of the magnetic flux.

Abstract: Embodiments of the present invention generally provide a plasma source apparatus, and method of using the same, that is able to generate radicals and/or gas ions in a plasma generation region that is symmetrically positioned around a magnetic core element by use of an electromagnetic energy source. In general, the orientation and shape of the plasma generation region and magnetic core allows for the effective and uniform coupling of the delivered electromagnetic energy to a gas disposed in the plasma generation region. In general, the improved characteristics of the plasma formed in the plasma generation region is able to improve deposition, etching and/or cleaning processes performed on a substrate or a portion of a processing chamber that is disposed downstream of the plasma generation region.

Abstract: A system and method for generating and using plasma is provided. An embodiment comprises a plasma generating unit that comprises beta-phase aluminum oxide. A precursor material is introduced to the plasma generating unit and a plasma is induced from the precursor material. The plasma may be used to deposit or etch materials on a semiconductor substrate.

Abstract: A plasma generator has a first member 2 containing a dielectric material, and an electrode group composed of a plurality of electrodes and including a first assembly 6 partially including a plurality of electrodes and a second assembly 7 partially including a plurality of electrodes. In accordance with an AC voltage, the first assembly 6 generates a plasma in a first space 23 contacting the first member 2. In accordance with a DC voltage, the second assembly 7 generates an electric field in a second space 24 contacting the first member 2 and communicating with the first space 23. At least one or more electrodes of a portion of the first assembly 6 and at least one or more electrodes of a portion of the second assembly 7 are provided on the surface of or in the inside of the first member 2.

Abstract: Systems and methods may be provided for cylindrical Hall thrusters with independently controllable ionization and acceleration stages. The systems and methods may include a cylindrical channel having a center axial direction, a gas inlet for directing ionizable gas to an ionization section of the cylindrical channel, an ionization device that ionizes at least a portion of the ionizable gas within the ionization section to generate ionized gas, and an acceleration device distinct from the ionization device. The acceleration device may provide an axial electric field for an acceleration section of the cylindrical channel to accelerate the ionized gas through the acceleration section, where the axial electric field has an axial direction in relation to the center axial direction. The ionization section and the acceleration section of the cylindrical channel may be substantially non-overlapping.

Abstract: This disclosure describes systems, methods, and apparatus for capacitively coupling energy into a plasma to ignite and sustain the plasma within a remote plasma source. The power is provided by a first electrode that at least partially surrounds or is surrounded by a second electrode. The second electrode can be grounded or floating. First and second dielectric components can be arranged to separate one or both of the electrodes from the plasma and thereby DC isolate the plasma from one or both of the electrodes.

Abstract: Provided is a plasma ignition technique allowing easy and reliable ignition and reignition of plasma without monitoring or manual handling. A plasma ignition system according to this technique is provided with a radio-frequency power supply configured to supply a predetermined high frequency signal to an applied electrode for generating plasma; a matching device configured to match impedance on a side of the radio-frequency power supply and impedance on a side of the applied electrode; a forward wave/reflected wave detector configured to detect a forward wave and a reflected wave of the high frequency signal; a high-voltage generator configured to generate a predetermined high voltage; and a controller configured to superimpose the high voltage on the high frequency signal when a ratio of the reflected wave to the forward wave is greater than a first threshold value.

Abstract: A Hall effect plasma thruster including an annular discharge channel around a main axis presenting an open downstream end and defined between an inner wall and an outer wall, at least one cathode, a magnetic circuit for creating a magnetic field in the channel, a pipe for feeding ionizable gas to the channel, an anode, and a manifold placed in the upstream end of the channel. The manifold is connected to the pipe and enables the ionizable gas to flow into the ionization zone of the channel in concentric manner around the main axis. The anode acts as a manifold, and the manifold includes a directional mechanism that gives rise at an outlet from the manifold to swirling motion of the gas around the main axis.

Abstract: A method for improving the uniformity of high-frequency discharge plasma by means of frequency modulation is disclosed. In a plasma discharge chamber, there is a pair of parallel electrodes. A high-frequency power supply is adopted to feed the electrodes. The frequency range of the electromagnetic field is 13.56 MHz˜160 MHz. Discharge gas is input to form plasma. The frequency of the fed-in high-frequency electromagnetic field is under automatic tuning control, and keeps changing cyclically without stop in the course of plasma discharge. The range of the frequency change may fall into either a portion of or the entire range of 13.56 MHz˜160 MHz and makes the locations with higher plasma density on the plane in parallel with the electrodes and in the plasma discharge space changed cyclically. In a time slot longer than one frequency change cycle, the average plasma density between the parallel electrodes is uniform.

Abstract: A plasma source generates a plasma beam that is extracted from a plasma generated by electric and magnetic fields. An RF electrode device includes an excitation electrode having an excitation area, and a plasma space is arranged between extraction electrode and excitation area. The plasma, relative to the extraction electrode is at a higher potential which accelerates positive plasma ions, and the plasma and the extracted plasma beam are influenced by a magnetic field. At least one magnet north pole and one magnetic south pole generate the magnetic field. Each are arranged such that a curved magnetic field projecting into the interior of the plasma space is formed. At least one of the north or south poles is embodied in elongate fashion to form a tunnel-like region in the plasma, in which charged particles are held and along which the latter can propagate.