Abstract: A method for controlling a plasma in a semiconductor substrate processing chamber is provided. The method includes the steps of supplying a first RF signal to a first electrode within the processing chamber at a first frequency selected to cause plasma sheath oscillation at the first frequency; and supplying a second RF signal from the source to the first electrode at a second frequency selected to cause plasma sheath oscillation at the second frequency, wherein the second frequency is different from the first frequency by a differential equal to a desired frequency selected to cause plasma sheath oscillation at the desired frequency.

Abstract: A method of controlling a plasma processing according to trajectories connecting start and stop values of parameters controlling the plasma processing, for example, gas flow and power supplied to generate the plasma. The trajectories maybe based on equations including at least time as a variable. At set times within the processing, the values of the parameters are updated according to the predetermined trajectories. Sensors associated with the chamber may also adjust the trajectories, provide variables to the equations, and/or define the trajectories.

Abstract: A method and apparatus for generating and controlling a plasma in a semiconductor substrate processing chamber using a dual frequency RF source is provided. The method includes the steps of supplying a first RF signal from the source to an electrode within the processing chamber at a first frequency and supplying a second RF signal from the source to the electrode within the processing chamber at a second frequency. The second frequency is different from the first frequency by an amount equal to a desired frequency. Characteristics of a plasma formed in the chamber establish a sheath modulation at the desired frequency.

Abstract: A plasma reactor for processing a workpiece includes a gas distribution showerhead having a lid, a manifold having a top surface facing the lid and a bottom surface opposing the top surface. Top surface channels in the manifold top surface form a first set of plural paths extending from a first gas input point to plural path ends of the top surface channels. Gas distribution orifices extend axially through the manifold at respective ones of the path ends. Bottom surface channels in the manifold bottom surface form plural paths extending from locations at each of the gas distribution orifices to plural gas distribution path ends. The showerhead further includes a showerhead piece facing the manifold bottom surface and having plural gas injection orifices extending through the showerhead piece.

Abstract: An apparatus for processing a substrate has a chamber, a high frequency power source, and a low frequency power source. The chamber has a first and second electrode disposed therein. The high frequency power source is electrically coupled to either the first or second electrode to supply a first RF signal. The low frequency power source electrically coupled to either the first or second electrode to supply a second RF signal. The first RF signal is pulsed on and off so as to enhance electron loss in the chamber.

Abstract: A method of processing a workpiece in the chamber of a plasma reactor having a ceiling overlying the workpiece by introducing a process gas into the chamber through a gas distribution plate in the ceiling. The gas is introduced by distributing gas flow from a first gas input to plural gas distribution orifices extending through a manifold of the gas distribution plate, and distributing gas flow from each of the plural gas distribution orifices to plural gas injection orifices in a showerhead of the gas distribution plate. The method further includes restricting gas flow in the gas distribution plate to paths having arcuate lengths about an axis of symmetry less than a complete circle. The method also includes capacitively and inductively coupling plasma source power into the chamber through the gas distribution.

Abstract: A method of processing a workpiece in a plasma reactor chamber is disclosed. The method includes providing an in-situ gas distribution plate between the workpiece and a ceiling of the chamber that divides the chamber into upper and lower chamber regions. The method further includes providing in the in-situ plate an array of feed-through openings with different opening sizes to present a non-uniform distribution of gas flow resistance for gas flow from the upper chamber region to the lower chamber region. A first process gas is introduced into the upper chamber region and a plasma is generated a plasma in the upper chamber region. A second process gas is introduced in the lower chamber region through gas injection orifices of the in-situ gas distribution plate.

Abstract: A plasma reactor is provided for processing a workpiece such as a semiconductor wafer or a dielectric mask. The reactor chamber has a ceiling, a side wall and a workpiece support pedestal inside the chamber and facing the ceiling along an axis of symmetry and defining a chamber volume between the pedestal and the ceiling. An RF plasma source power applicator is provided at the ceiling. An in-situ electrode body inside the chamber lies divides the chamber into upper and lower chamber regions. The in-situ electrode comprises plural flow-through passages extending parallel to the axis and having different opening sizes, the passages being radially distributed by opening size in accordance with a desired radial distribution of gas flow resistance through the in-situ electrode body.

Abstract: An RF blocking filter isolates a two-phase AC power supply from at least 2 kV p-p of power of an HF frequency that is reactively coupled to a resistive heating element, while conducting several kW of 60 Hz AC power from the two-phase AC power supply to the resistive heating element without overheating, the two-phase AC power supply having a pair of terminals and the resistive heating element having a pair of terminals. The filter includes a pair of cylindrical non-conductive envelopes each having an interior diameter between about one and two inches and respective pluralities of fused iron powder toroids of magnetic permeability on the order of about 10 stacked coaxially within respective ones of the pair of cylindrical envelopes, the exterior diameter of the toroids being about the same as the interior diameter of each of the envelopes. A pair of wire conductors of diameter between 3 mm and 3.

Abstract: The present invention generally provides methods and apparatuses that are adapted to form a high quality dielectric gate layer on a substrate. Embodiments contemplate a method wherein a metal plasma treatment process is used in lieu of a standard nitridization process to form a high dielectric constant layer on a substrate. Embodiments further contemplate an apparatus adapted to “implant” metal ions of relatively low energy in order to reduce ion bombardment damage to the gate dielectric layer, such as a silicon dioxide layer and to avoid incorporation of the metal atoms into the underlying silicon. In general, the process includes the steps of forming a high-k dielectric and then terminating the surface of the deposited high-k material to form a good interface between the gate electrode and the high-k dielectric material.

Abstract: The present invention generally provides methods and apparatuses that are adapted to form a high quality dielectric gate layer on a substrate. Embodiments contemplate a method wherein a metal plasma treatment process is used in lieu of a standard nitridization process to form a high dielectric constant layer on a substrate. Embodiments further contemplate an apparatus adapted to “implant” metal ions of relatively low energy in order to reduce ion bombardment damage to the gate dielectric layer, such as a silicon dioxide layer and to avoid incorporation of the metal atoms into the underlying silicon. In general, the process includes the steps of forming a high-k dielectric and then terminating the surface of the deposited high-k material to form a good interface between the gate electrode and the high-k dielectric material.

Abstract: The present invention generally provides methods and apparatuses that are adapted to form a high quality dielectric gate layer on a substrate. Embodiments contemplate a method wherein a metal plasma treatment process is used in lieu of a standard nitridization process to form a high dielectric constant layer on a substrate. Embodiments further contemplate an apparatus adapted to “implant” metal ions of relatively low energy in order to reduce ion bombardment damage to the gate dielectric layer, such as a silicon dioxide layer and to avoid incorporation of the metal atoms into the underlying silicon. In general, the process includes the steps of forming a high-k dielectric and then terminating the surface of the deposited high-k material to form a good interface between the gate electrode and the high-k dielectric material.

Abstract: A plasma reactor includes a toroidal plasma source having an RF power applicator, and RF generator being coupled to the RF power applicator. The reactor further includes a capacitively coupled plasma source power applicator or electrode at the ceiling or the workpiece support, a VHF power generator being coupled to the capacitively coupled source power applicator, a plasma bias power applicator or electrode in the workpiece support and an RF bias power generator coupled to the plasma bias power applicator. A controller adjusts the relative amounts of power simultaneously coupled to plasma in the chamber and conduit by the toroidal plasma source and by the capacitively coupled plasma source power applicator.

Abstract: A glass workpiece being processed in a vacuum plasma processing chamber is dechucked from a monopolar electrostatic chuck by gradually reducing the chucking voltage during processing while maintaining the voltage high enough to clamp the workpiece. A reverse polarity voltage applied to the chuck at the end of processing assists in dechucking. The workpiece temperature is maintained at a high value at the end of processing to assisting in dechucking. Peak current flowing through the chuck during lifting of the workpiece from the chuck controls the amplitude and/or duration of the reverse polarity voltage during the next dechucking operation.

Abstract: A method and apparatus for processing wafers including a chamber defining a plurality of isolated processing regions. The isolated processing regions have an upper end and a lower end. The chamber further includes a plurality of plasma generation devices each disposed adjacent the upper end of each isolated processing region, and one of a plurality of power supplies connected to each plasma generation device. The output frequency of the plurality of power supplies are phase and/or frequency locked together. Additionally, the chamber includes a plurality of gas distribution assemblies. Each gas distribution assembly is disposed within each isolated processing region. A movable wafer support is disposed within each isolated processing region to support a wafer for plasma processing thereon. The movable wafer support includes a bias electrode coupled to a bias power supply configured to control the bombardment of plasma ions toward the movable wafer support.

Abstract: A substrate is placed in a process zone and an energized process gas is maintained in the process zone to process the substrate. A light beam is reflectively diffracted from a pattern of features of the substrate being processed, the reflected beam is monitored, and a signal is generated in relation to the monitored beam. During processing, a width of the features of the substrate can change. The generated signal is evaluated to detect the occurrence of a change in the width of the features.

Abstract: A glass workpiece being processed in a vacuum plasma processing chamber is dechucked from a monopolar electrostatic chuck by gradually reducing the chucking voltage during processing while maintaining the voltage high enough to clamp the workpiece. A reverse polarity voltage applied to the chuck at the end of processing assists in dechucking. The workpiece temperature is maintained at a high value at the end of processing to assisting in dechucking. Peak current flowing through the chuck during lifting of the workpiece from the chuck controls the amplitude and/or duration of the reverse polarity voltage during the next dechucking operation.

Abstract: A substrate is placed in a process zone and an energized process gas is maintained in the process zone to process the substrate. A light beam is reflectively diffracted from a pattern of features of the substrate being processed, the reflected beam is monitored, and a signal is generated in relation to the monitored beam. During processing, a width of the features of the substrate can change. The generated signal is evaluated to detect the occurrence of a change in the width of the features.

Abstract: One embodiment of the present invention is an etching method for use in fabricating an integrated circuit device on a wafer or substrate in an inductively coupled plasma reactor in a passivation-driven etch chemistry, which method includes steps of: (a) providing a passivation-driven etch chemistry precursor in a chamber of the reactor wherein a first coil is disposed to supply energy primarily to an outer portion of the chamber and a second coil is disposed to supply energy primarily to an inner portion of the chamber; and (b) providing power to the first coil and the second coil in a ratio of power supplied to the first coil and power supplied to the second coil greater than 1.

Abstract: A method and apparatus for processing wafers including a chamber defining a plurality of isolated processing regions. The isolated processing regions have an upper end and a lower end. The chamber further includes a plurality of plasma generation devices each disposed adjacent the upper end of each isolated processing region, and one of a plurality of power supplies connected to each plasma generation device. The output frequency of the plurality of power supplies are phase and/or frequency locked together. Additionally, the chamber includes a plurality of gas distribution assemblies. Each gas distribution assembly is disposed within each isolated processing region. A movable wafer support is disposed within each isolated processing region to support a wafer for plasma processing thereon. The movable wafer support includes a bias electrode coupled to a bias power supply configured to control the bombardment of plasma ions toward the movable wafer support.