Abstract: The invention is embodied in an inductively coupled RF plasma reactor including a reactor chamber enclosure defining a plasma reactor chamber and a support for holding a workpiece inside the chamber, a non-planar inductive antenna adjacent the reactor chamber enclosure, the non-planar inductive antenna including inductive elements spatially distributed in a non-planar manner relative to a plane of the workpiece to compensate for a null in an RF inductive pattern of the antenna, and a plasma source RF power supply coupled to the non-planar inductive antenna. The planar inductive antenna may be symmetrical or non-symmetrical, although it preferably includes a solenoid winding such as a vertical stack of conductive windings. In a preferred embodiment, the windings are at a minimum radial distance from the axis of symmetry while in an alternative embodiment the windings are at a radial distance from the axis of symmetry which is a substantial fraction of a radius of the chamber.

Abstract: A radio frequency plasma multiple-coil antenna allows for controllable, uniform inductive coupling within a plasma reactor. According to exemplary embodiments, multiple coils are positioned on a dielectric window of a plasma chamber, and are powered by a single radio frequency generator and tuned by a single matching network. Each coil is either planar or a combination of a planar coil and a vertically stacked helical coil. The input end of each coil is connected to an input tuning capacitor and the output end is terminated to the ground through an output tuning capacitor. The location of the maximum inductive coupling of the radio frequency to the plasma is mainly determined by the output capacitor, while the input capacitor is mainly used to adjust current magnitude into each coil.

Abstract: The processing chamber of an etching apparatus is divided into a plasma generating space and a processing space by a grid electrode. A first feed gas is supplied from a gas source unit to the plasma generating space through a first flow control valve mechanism and a first gas supply line. A second feed gas is supplied from the gas source unit to the processing space through a second flow control valve mechanism and a second gas supply line. The interior of the processing chamber is evacuated by an exhaust pump through an exhaust line connected to the processing space. Each of the first and second flow control valve mechanisms has a plurality of valves whose opening degrees are separately controlled by a CPU.

Abstract: Radio frequency plasma coupling systems allow for controllable, uniform inductive coupling within a plasma reactor, as well as separately controllable, uniform capacitive coupling within the reactor. According to exemplary embodiments, a set of parallel coupling elements are positioned on a dielectric window of a plasma chamber, and the positioning of the elements and/or a set of phase shifters situated between the elements are used to force the radio frequency current flowing within the elements to be oriented in a common direction. Consequently, the inductively coupled fields generated by the elements are reinforcing, and induce a highly uniform plasma in the reactor. Further, the electrical characteristics of the elements are such that independently controllable and highly uniform capacitive coupling can be provided in order to prevent polymer buildup on components within the reactor.

Abstract: An apparatus for forming an electromagnetic field in a processing chamber, including a first pair of electrodes for generating a first electromagnetic field within the processing chamber and a second pair of electrodes for generating a second electromagnetic field within the processing chamber. The first and second pairs of electrodes are oriented so that the first and second electromagnetic fields are oriented generally perpendicular to each other. When energized, the first and second electromagnetic fields combine and may take the form of a lissajous pattern. When a gas is exposed to the combined electromagnetic field a plasma may be formed in the general shape of the combined electromagnetic field.

Abstract: A film forming/modifying system includes a film forming apparatus which has an alcohol supply unit and forms a metal oxide film on a semiconductor wafer in a vacuum atmosphere in which a vaporized metal oxide film material and a vaporized alcohol exist, a film modifying apparatus which has a UV irradiation unit for irradiating a UV ray on ozone to generate active oxygen atoms, and modifies the metal oxide film by exposing the metal oxide film to the active oxygen atoms in a vacuum atmosphere, and a common transfer chamber commonly coupled to the film forming apparatus and the film modifying apparatus to transfer the target process object between the film forming apparatus and the film modifying apparatus while maintaining the vacuum state.

Abstract: A plasma process reactor is disclosed that allows for greater control in varying the functional temperature range for enhancing semiconductor processing and reactor cleaning. The temperature is controlled by splitting the process gas flow from a single gas manifold that injects the process gas behind the gas distribution plate into two streams where the first stream goes behind the gas distribution plate and the second stream is injected directly into the chamber. By decreasing the fraction of flow that is injected behind the gas distribution plate, the temperature of the gas distribution plate can be increased. The increasing of the temperature of the gas distribution plate results in higher O.sub.2 plasma removal rates of deposited material from the gas distribution plate. Additionally, the higher plasma temperature aids other processes that only operate at elevated temperatures not possible in a fixed temperature reactor.

Abstract: An external inductive coil is used in a plasma process system having a dielectric shield which separates the coil from the plasma. The shield includes channels provided along the inner side of the shield facing the plasma region. The channels inhibit the formation of a continuous metal film over the inner surface of the shield during sputtering and deposition. The sidewalls defining the channels permit RF transmission after the surfaces directly facing the plasma are coated with metal.

Abstract: An apparatus comprising a semiconductor processing chamber, a plasma generator, and a pipe connecting a semiconductor processing chamber and the plasma generator. The plasma generator includes a generation chamber, a radio frequency generator which generates an ion plasma within the generation chamber, a magnetic device which confines the plasma primarily within a center region of the generation chamber, and a thermally conductive member disposed around the outer surface of the generation chamber for removing heat away from the chamber.

Abstract: A constriction in the exhaust side of a discharge chamber containing oxygen isolates the oxygen supply from the rest of the system. A constriction of equal size or larger is used in the supply of another gas, thereby enabling mixtures of oxygen and other gases to be used in a downstream plasma system. In one embodiment of the invention, the gases are dissociated separately and then combined in a mixing chamber. In another embodiment, oxygen is dissociated and then a lighter gas is added and the mixture is dissociated. In a preferred embodiment of the invention, the lighter gas is selected from the group consisting of water vapor and nitrogen.

Abstract: A chemical vapor deposition (CVD) system of the type having an enclosure housing a process chamber and a supply of cleaning gas, features a lid having a base plate with opposed first and second major surfaces and a plurality of throughways extending therebetween to provide an asymmetric flow of cleaning gas into the chamber. Specifically, a subportion of the second major surface lies in a plane of truncation and faces the process chamber when the lid is in a closed position. The remaining portions of the second major surface are recessed, defining central and annular recesses. The annular recess has a base surface and two spaced-apart side surfaces extending from the base surface and terminating proximate to the plane of truncation. The plurality of throughways consists of primary and secondary throughways, each of which extends from an opening in the first major surface and terminates in an orifice.

Abstract: The present invention provides an HDP-CVD tool using simultaneous deposition and sputtering of doped and undoped silicon dioxide capable of excellent gap fill and blanket film deposition on wafers. The tool of the present invention includes: a dual RF zone inductively coupled plasma source; a dual zone gas distribution system; temperature controlled surfaces within the tool; a symmetrically shaped turbomolecular pumped chamber body; a dual cooling zone electrostatic chuck; an all ceramic/aluminum alloy chamber; and a remote plasma chamber cleaning system.

Abstract: Methods of forming tungsten-comprising layers are described. In one implementation, a substrate is provided having a surface over which a tungsten-comprising layer is to be formed. A gas plasma is generated comprising a reactive species, with the substrate not being exposed to the gas plasma. The reactive species from the gas plasma and a source gas comprising tungsten are provided into proximity with the substrate surface and under conditions which are effective to form a tungsten-comprising layer over at least a portion of the surface. In another implementation, a tungsten source gas is provided into a chamber having a substrate positioned therein. A gaseous reactive species formed from a gas plasma is provided into proximity with the substrate within the chamber and under conditions which are effective to form a layer comprising tungsten over at least a portion of the substrate.

Abstract: Controlling ion/radical ratio and monoatomic/polyatomic radical ratio in a process plasma provides improved processing performance during inductively-coupled plasma and/or helicon wave plasma processing of substrate materials. In a plasma processing method employing inductively coupled plasma, high frequency current to a high frequency antenna is intermittently supplied in a controlled manner to control the state of gas dissociation to promote formation of polyatomic radicals. In a plasma processing method employing helicon wave plasma, current supplied to a magnetic field generator is intermittently supplied in a controlled manner to promote formation of ions. In a preferred method, both the high frequency current and magnetic field generating current are varied in a controlled manner to provide a variable plasma composition, i.e., radical rich plasma or ion-rich plasma, as desired, for improved plasma processing, especially improved selective anisotropic dry etching at high etch rate.

Abstract: A method for controlling the voltage distribution of the standing wave impressed upon the coil of an inductively coupled plasma generator includes the steps of impressing a radio frequency voltage across the coil to establish a standing wave thereacross. A voltage profile is selected for the standing wave so as to control the location and amount of capacitive coupling. A circuit parameter is controlled to achieve the selected voltage profile. Proper selection of the voltage profile enhances process capabilities, decreases the time between cleans, minimizes component wear, and minimizes cleaning time. An apparatus for carrying out the disclosed method is also disclosed.

Abstract: The present invention provides a plasma processing system comprising a remote plasma activation region for formation of active gas species, a transparent transfer tube coupled between the remote activation region and a semiconductor processing chamber, and a source of photo energy for maintaining activation of the active species during transfer from the remote plasma activation region to the processing chamber. The source of photo energy preferably includes an array of UV lamps. Additional UV lamps may also be used to further sustain active species and assist plasma processes by providing additional in-situ energy through a transparent window of the processing chamber.

Abstract: A plasma etching apparatus of the induction coupling type for processing an LCD substrate has a process container forming an airtight process room. A work table is arranged in the process room for supporting the LCD substrate. A vacuum pump is arranged for exhausting and setting the process room into a vacuum state. An antenna block having a plurality of dielectric layers is arranged to face the work table. An RF antenna is embedded in one of the dielectric layers of the antenna block for forming an electric field. A power supply is connected to the RF antenna for applying an RF power. The lowermost layer of the antenna block is formed as a shower head for supplying a process gas into the process room from a position between the RF antenna and the work table. At least part of the process gas is turned into plasma by the electric field.

Abstract: A plasma processing device (25) including a vacuum chamber (27) for processing a substrate (29) and a source chamber (26) for generating a plasma is disclosed where the source chamber (26) has a non-cylindrical geometry. Helicon waves of plasma are propagated from the source chamber into the vacuum chamber by a magnetic field having substantially parallel magnetic field lines extending from the source chamber into the vacuum chamber. A RF antenna (31 and 32) of a novel serpentine configuration is used to couple electromagnetic energy into the source chamber to create helicon plasma waves in the source chamber (26). The non-cylindrical geometry of the source chamber allows the processing of large area substrates due to the ability to scale the source chamber to the desired application while maintaining throughput efficiency and the ability to propagate helicon waves along the magnetic field lines present in the source chamber.

Abstract: An apparatus is provided for controlling the flow of gaseous reactants in a CVD reactor through the use of a body having interior and exterior regions, in which the body defines at least one flow path between the interior and exterior regions so as to create a pressure drop from the interior to the exterior of the body within the chamber. The body is disposed in a reaction chamber with a first area proximate a gaseous reactant inlet and a second area proximate a substrate support such that the substrate is positioned in proximity to the interior of the body. As such, gaseous reactants introduced into the interior of said chamber through the inlet create a pressure drop between the interior and the exterior of the body. In a preferred embodiment, the body is cylindrically shaped and contains perforations providing the flow paths. Preferably, the perforations are either more numerous or larger in the second area than the first area to create a pressure gradient in the interior of the body.

Abstract: In accordance with a first aspect of the invention, a plasma reactor having a chamber for containing a plasma and a passageway communicating with the chamber is enhanced with a first removable plasma confinement magnet module placed adjacent the passageway including a first module housing and a first plasma confinement magnet inside the housing. It may further include a second removable plasma confinement magnet module placed adjacent the passageway including a second module housing, and a second plasma confinement magnet. Preferably, the first and second modules are located on opposite sides of the passageway. Moreover, the first and second plasma confinement magnets have magnetic orientations which tend to oppose plasma transport or leakage through the passageway. Preferably, the module housing includes a relatively non-magnetic thermal conductor such as aluminum and is in thermal contact with said chamber body.

Abstract: In a vapor deposition chamber which holds a substrate for processing, a method including the steps of forming a layer of material on the surface of the substrate, wherein the layer of material is made of Ti atoms; remotely activating a source gas containing nitrogen so as to produce activated nitrogen gas species; and while forming the layer of material on the substrate, injecting the activated nitrogen species into the processing chamber to increase the population of activated nitrogen species that is incorporated into the layer of material that is being formed.

Abstract: The invention is embodied in a plasma reactor including a plasma reactor chamber and a workpiece support for holding a workpiece near a support plane inside the chamber during processing, the chamber having a reactor enclosure portion facing the support, a cold body overlying the reactor enclosure portion, a plasma source power applicator between the reactor enclosure portion and the cold body and a thermally conductor between and in contact with the cold body and the reactor enclosure. The thermal conductor and the cold sink define a cold sink interface therebetween, the reactor preferably further including a thermally conductive substance within the cold sink interface for reducing the thermal resistance across the cold sink interface. The thermally conductive substance can be a thermally conductive gas filling the cold body interface. Alternatively, the thermally conductive substance can be a thermally conductive solid material.

Abstract: A plasma reactor and methods for processing semiconductor substrates are described. An induction coil inductively couples power into the reactor to produce a plasma. A thin electrostatic shield is interposed between the induction coil and plasma to reduce capacitive coupling. The shield is electromagnetically thin such that inductive power passes through the shield to sustain the plasma while capacitive coupling is substantially attenuated. Reducing capacitive coupling reduces modulation of the plasma potential relative to the substrate and allows for more controllable processing.

Abstract: An apparatus and method of producing a negative ion plasma for use in manufacturing of microelectronic devices, particularly etching of microelectronic patterns in semiconductor wafers. A negative ion plasma is produced from a hot electron plasma formed by a RF or UHF plasma source. The negative ion plasma includes positive ions, negative ions and relatively cold electrons, such electrons having an effective electron temperature or average energies less than that for maintaining the plasma. The fields producing the hot plasma are isolated from the negative ion plasma in a cold plasma region by a magnetic filter. The magnetic filter confines the plasmas to provide plasma uniformity at a work piece being etched by the negative ion plasma. The magnetic filter further prevents hot electrons originating in the hot electron plasma from diffusing into the negative ion plasma, while allowing positive ions and cold electrons to diffuse from the hot plasma to the negative ion plasma.

Abstract: On the bottom of a chamber, there is provided a lower electrode for supporting an object to be processed with intervention of an insulator. A first RF power source applies RF power to a multiple spiral coil composed of four spiral coil elements connected in parallel via an impedance matcher. The length of each of the coil elements corresponds to 1/4 of the wavelength of the RF power supplied from the first RF power source. A second RF power source applies an RF bias voltage to the lower electrode.

Abstract: The invention is embodied by a plasma reactor for processing a workpiece, including a reactor enclosure defining a processing chamber, a semiconductor ceiling window, a base within the chamber for supporting the workpiece during processing thereof, the semiconductor ceiling including a gas inlet system for admitting a plasma precursor gas into the chamber through the ceiling, and apparatus for coupling plasma source power into the chamber.

Abstract: A general method of the invention is to provide a polymer-hardening precursor piece (such as silicon, carbon, silicon carbide or silicon nitride, but preferably silicon) within the reactor chamber during an etch process with a fluoro-carbon or fluoro-hydrocarbon gas, and to heat the polymer-hardening precursor piece above the polymerization temperature sufficiently to achieve a desired increase in oxide-to-silicon etch selectivity. Generally, this polymer-hardening precursor or silicon piece may be an integral part of the reactor chamber walls and/or ceiling or a separate, expendable and quickly removable piece, and the heating/cooling apparatus may be of any suitable type including apparatus which conductively or remotely heats the silicon piece.

Abstract: An enhanced inductively coupled plasma reactor which comprises; a chamber; a power supply for providing radio-frequencies necessary to generate plasma within the chamber; an antenna for producing electric fields and magnetic fields with a radio-frequency power from the power supply to generate plasma within the chamber; Helmholtz coils for shaking the plasma with intermittent modulation of a weak magnetic field to increase the density of the plasma and decrease the electron temperature and enhance the uniformity of the plasma, the Helmholtz coils consisting of two coils which are symmetrically arranged with a common axis, winding around the chamber at an upper position and a lower position, respectively, the weak magnetic field being produced by providing a combination of a direct current and an alternating current to the Helmholtz coils; a wafer stage and support; a bias RF power supply for controlling ion energies, connected to the wafer stage; and a matching box for optimally controlling and transferring t

Abstract: A plasma processing apparatus is furnished with a reactor which is furnished with a susceptor 12, a reaction gas delivery mechanism which delivers reaction gas to the inside of the reactor, a pumping mechanism 24 which pumps out an interior of the reactor, and a plasma-generating mechanism. The reactor is made of metal, the plasma-generating mechanism includes an at least single-winding coil 16 which produces an induced electric field, and the coil is established within the reactor and surrounding the plasma-generating space in a state surrounded by dielectrics parts 15 and 17.

Abstract: The invention is embodied in a magnetically enhanced plasma reactor for processing a semiconductor workpiece, including a reactor enclosure defining a vacuum chamber, a wafer support for holding the workpiece inside the chamber, a plasma power source for applying plasma source power into the chamber, a first plurality of electrically conductive elongate filaments, each being of a finite length, distributed about a periphery of the chamber enclosure, each of said filaments extending at least generally in an axial direction relative to the chamber. The plurality of filaments is capable of permitting different currents through different ones of at least some of the filaments in accordance with a distribution of currents among the filaments corresponding to a desired magnetic field configuration. Respective current sources are preferably connected to deliver respective currents to different ones of the plurality of filaments.

Abstract: A plasma etch reactor having independent gas feeds above the wafer and either at the sides or below the wafer. Preferably, a carrier gas such as argon is supplied from a showerhead electrode above the wafer while an etching gas is supplied from below. In the case of selectively etching an oxide over a non-oxide layer, the etchant gas should include one or more fluorocarbons.

Abstract: Apparatus and method for an improved etch process. A power source alternates between high and low power cycles to produce and sustain a plasma discharge. Preferably, the high power cycles couple sufficient power into the plasma to produce a high density of ions (>10.sup.11 cm.sup.-3) for etching. Preferably, the low power cycles allow electrons to cool off to reduce the average random (thermal) electron velocity in the plasma. Preferably, the low power cycle is limited in duration as necessary to prevent excessive plasma loss to the walls or due to recombination of negative and positive ions. It is an advantage of these and other aspects of the present invention that average electron thermal velocity is reduced, so fewer electrons overcome the plasma sheath and accumulate on substrate or mask layer surfaces. A separate power source alternates between high and low power cycles to accelerate ions toward the substrate being etched. In one embodiment, a strong bias is applied to the substrate in short bursts.

Abstract: In one aspect, the invention is embodied in an RF inductively coupled plasma reactor including a vacuum chamber for processing a wafer, one or more gas sources for introducing into the chamber reactant gases, and an antenna capable of radiating RF energy into the chamber to generate a plasma therein by inductive coupling, the antenna lying in a two-dimensionally curved surface. In another aspect, invention is embodied in a plasma reactor including apparatus for spraying a reactant gas at a supersonic velocity toward the portion of the chamber overlying the wafer. In a still further aspect, the invention is embodied in a plasma reactor including a planar spray showerhead for spraying a reactant gas into the portion of the chamber overlying the wafer with plural spray nozzle openings facing the wafer, and plural magnets in an interior portion of the planar spray nozzle between adjacent ones of the plural nozzle openings, the plural magnets being oriented so as to repel ions from the spray nozzle openings.

Abstract: A process for fabricating a product including the steps of subjecting a substrate to a composition of entities, at least one of the entities emanating from a species generated by a plasma excited by a high frequency field provided by an inductive coupling structure in which the phase and anti-phase capacitive currents into the plasma are substantially balanced.

Abstract: Atmospheric-pressure plasma jet. A .gamma.-mode, resonant-cavity plasma discharge that can be operated at atmospheric pressure and near room temperature using 13.56 MHz rf power is described. Unlike plasma torches, the discharge produces a gas-phase effluent no hotter than 250.degree. C. at an applied power of about 300 W, and shows distinct non-thermal characteristics. In the simplest design, two concentric cylindrical electrodes are employed to generate a plasma in the annular region therebetween. A "jet" of long-lived metastable and reactive species that are capable of rapidly cleaning or etching metals and other materials is generated which extends up to 8 in. beyond the open end of the electrodes. Films and coatings may also be removed by these species. Arcing is prevented in the apparatus by using gas mixtures containing He, which limits ionization, by using high flow velocities, and by properly shaping the rf-powered electrode.

Abstract: A plasma reactor has plural dielectric gas injection tubes extending from a gas injection source and through a microwave guide and into the top of the reactor chamber. The semiconductor wafer rests near the bottom of the chamber on a wafer pedestal connected to a bias RF power source which is controlled independently of the microwave source coupled to the microwave guide. The microwaves from the waveguide ignite and maintain a plasma in each of the tubes. Gas flow through the tubes carries the plasmas in all the tubes into the chamber and into contact with the wafer surface.

Abstract: An apparatus is provided for controlling the flow of gaseous reactants in a CVD reactor through the use of a body having interior and exterior regions, in which the body defines at least one flow path between the interior and exterior regions so as to create a pressure drop from the interior to the exterior of the body within the chamber. The body is disposed in a reaction chamber with a first area proximate a gaseous reactant inlet and a second area proximate a substrate support such that the substrate is positioned in proximity to the interior of the body. As such, gaseous reactants introduced into the interior of said chamber through the inlet create a pressure drop between the interior and the exterior of the body. In a preferred embodiment, the body is cylindrically shaped and contains perforations providing the flow paths. Preferably, the perforations are either more numerous or larger in the second area than the first area to create a pressure gradient in the interior of the body.

Abstract: A low pressure plasma ignition method and apparatus includes an ignition cylinder which passes through an anode of a vacuum chamber, where the outlet of the ignition cylinder forms a nozzle. A coil is arranged around the cylinder and a plasma-generating gas supply pipe passes through an upper part of the cylinder. A plasma-generating gas, such as Argon gas, is supplied to the ignition cylinder in this structure, such that a high density plasma is formed in the ignition cylinder that is expelled into the vacuum chamber while the pressure is reduced through the nozzle. In the vacuum chamber, the expelled plasma becomes a seed plasma, such that a low pressure plasma is readily generated in the vacuum chamber.

Abstract: The invention is embodied in a plasma reactor having a vacuum chamber with a cylindrical side portion and a ceiling at a certain height above the top of the cylindrical side portion, a wafer-holding pedestal near the bottom of the vacuum chamber, gas injection ports near the cylindrical side portion and a vacuum pump, the reactor including a generally planar disk-shaped conductive ceiling electrode adjacent the ceiling, a helical coil antenna having a bottom winding near the top of the cylindrical side portion and a top winding generally corresponding to the second diameter near the planar disk-shaped conductive ceiling electrode, the helical coil antenna substantially spanning the height between the top of the cylindrical side portion and the ceiling, and a switch for individually connecting each one of the coil antenna, the ceiling electrode and the wafer pedestal to one of (a) a respective RF power source or (b) ground or (c) a floating potential (i.e., unconnected to any potential source).

Abstract: The present invention relates to a reaction apparatus for receiving a reaction gas and for heating a substrate so as to form a film such as an insulating film on the substrate or for etching, with reduced power consumption for heating the substrate. The apparatus can change a substrate temperature within a short period of time, and maintains throughput while reducing labor and cost for maintenance. The apparatus includes a substrate holder (12) with a base of an insulating material in which an electrode (22) and a heater (23) for heating the held substrate (20) are contained. The apparatus also includes a processing chamber (7) enclosed by a chamber wall (7a).

Abstract: A vacuum processing system for executing processing with plasma. The system includes plasma arrival prevention magnets for forming a magnetic field along the inner face of a vacuum vessel to prevent plasma from arriving at the inner face of the vacuum vessel, and a move mechanism for relatively moving the plasma arrival prevention magnets or the vacuum vessel so as to compensate vector unevenness of the plasma arrival prevention magnets in a direction of the inner face of the vacuum vessel for uniformly depositing a thin film on the inner face. The move mechanism moves the plasma arrival prevention magnets or the vacuum vessel during the vacuum processing interim and at the etching removal of the thin film deposited on the inner face of the vacuum vessel.

Abstract: Plasma processing gas is introduced into an upper portion of a processing vessel and a film-formation gas is simultaneously introduced into the vicinity of a substrate to be processed. The plasma processing gas is ionized to form a first plasma and any of the plasma processing gas that has temporarily recombined in locations close to the substrate to be processed is re-ionized as a second plasma. As a result, the density of etchant ions used for cutting away overhangs around the openings of grooves can be increased. In other words, the number of etchant ions can be increased. This makes it possible to reduce the bias voltage applied to the substrate to be processed, preventing damage thereto.

Abstract: An ICP (Inductively Coupled Plasma) system is used as a plasma generating means. A CVD process gas is introduced within a vacuum vessel from a gas inlet nozzle, and is then converted into plasma by a high frequency electric field induced within the vacuum vessel by an electromagnetic wave from an antenna. A sample can be located at a position not to be exposed to plasma, and a decomposed product material produced from the CVD process gas by the plasma is deposited on the surface of the sample mounted on a sample stage, thus forming a film. A dielectric viewing port, the antenna and the sample are disposed along the same axial direction such that the directions of the planes thereof correspond to each other, so that the film formation on the surface of the sample within the vacuum vessel can be observed through the transparent dielectric viewing port.

Abstract: A plasma reactor chamber uses an antenna driven by RF energy (LF, MF, or VHF) which is inductively coupled inside the reactor dome to provide a plasma source. The antenna generates a high density, low energy plasma inside the chamber. The chamber includes a plurality of magnets for generating magnetic fields. Ion flux is concentrated in certain areas of the chamber and is diverted from other areas of the chamber by using these magnetic fields. Various magnetic and voltage processing enhancement techniques are disclosed, along with etch processes, deposition processes and combined etch/deposition processes. The disclosed invention provides a means of cleaning the deposition residues from the reactor walls while minimizing damage to the wafer pedestal.

Abstract: An apparatus for generating plasma, includes a cylindrical vacuum chamber made of dielectric substance, the chamber being open only at a bottom thereof and having a height of 50 mm or smaller, at least one antenna coil disposed around the chamber for receiving high frequency power therein, and at least one electromagnetic coil disposed around the antenna coil. The cylindrical vacuum chamber may be replaced with a plate made of a dielectric substance. The apparatus is operative to carry out photoresist using etching without leaving any residue under a high selection ratio to the photoresist. In addition, the etching product does not tend to adhere to the vacuum chamber, and it would be easy to remove etching product from the vacuum chamber, even if the product adheres to the vacuum chamber.

Abstract: A plasma reactor and methods for processing semiconductor wafers are described. Gases are introduced into a reactor chamber. An induction coil surrounds the reactor chamber. RF power is applied to the induction coil and is inductively coupled into the reactor chamber causing a plasma to form. A split Faraday shield is interposed between the induction coil and the reactor chamber to substantially block the capacitive coupling of energy into the reactor chamber which may modulate the plasma potential. The configuration of the split Faraday shield may be selected to control the level of modulation of the plasma potential. For etch processes, a separate powered electrode may be used to accelerate ions toward a wafer surface. For isotropic etching processes, charged particles may be filtered from the gas flow, while a neutral activated species passes unimpeded to a wafer surface.

Abstract: A process for forming a deposited film on a substrate according to the chemical vapor deposition method comprises previously forming excited species of a gas phase compound containing atoms which become constituents constituting said deposited film, supplying the excited species onto the surface of said substrate and effecting photoirradiation on said substrate surface, thereby forming the deposited film through the surface reaction.

Abstract: A substantially planar coil of a vacuum plasma processor has plural turns for exciting gas in the processor to a plasma state in response to r.f. coil energization. The coil is located outside the processor and surrounded by a shield tending to cause magnetic flux coupled from peripheral portions of the coil to the gas to be less than magnetic flux coupled from interior portions of the coil to the gas. The coil is arranged so magnetic flux derived from a center portion of an area circumscribed by the coil is less than the magnetic flux derived from all other areas circumscribed by the coil. The magnetic flux is such that the density of the plasma in the processor on a processed substrate is relatively uniform even though the coil exhibits transmission line properties so there are substantial peak-to-peak current variations along the length of the coil.

Abstract: A plasma enhanced chemical processing reactor and method. The reactor includes a plasma chamber including a first gas injection manifold and a source of electromagnetic energy. The plasma chamber is in communication with a process chamber which includes a wafer support and a second gas manifold. The plasma generated in the plasma chamber extends into the process chamber and interacts with the reactive gases to deposit a layer of material on the wafer. The reactor also includes a vacuum system for exhausting the reactor. The method includes the steps of generating a plasma within the plasma chamber, introducing at least one gaseous chemical into the process chamber proximate to the wafer support and applying r.f. gradient to induce diffusion of the plasma to the area proximate the wafer support.

Abstract: A planar coil exciting a plasma of an r.f. vacuum plasma processor for a workpiece processed surface in a chamber includes plural turns. The coil, chamber and workpiece are arranged to produce in the chamber a magnetic flux having substantially greater density in peripheral portions of the coil and chamber than in a center portion of the chamber and coil so a substantially uniform plasma flux is incident on a processed surface of the workpiece.