Abstract: The present invention provides a temperature adjusting apparatus for a focus ring, wherein heat radiated from the plasma onto the focus ring is transferred downward to a base through the first heat conducting pad contacting a lower surface of the focus ring, an insulating ring contacting a lower surface of the first heat conducting pad, and the second heat conducting pad contacting a lower surface of the insulating ring, so as to be cooled by a cooling system provided at the base; turning on a heater disposed in a grounded shielding ring to generate a controllable external heating source, heat from the heater being transferred to the focus ring through the shielding ring, a third heat conducting pad contacting the shielding ring, the insulating ring contacting the third heat conducting pad, and the first heat conducting pad, so as to perform controllable warming to the focus ring.

Abstract: The present invention provides a temperature adjusting apparatus for a focus ring, wherein heat radiated from the plasma onto the focus ring is transferred downward to a base through the first heat conducting pad contacting a lower surface of the focus ring, an insulating ring contacting a lower surface of the first heat conducting pad, and the second heat conducting pad contacting a lower surface of the insulating ring, so as to be cooled by a cooling system provided at the base; turning on a heater disposed in a grounded shielding ring to generate a controllable external heating source, heat from the heater being transferred to the focus ring through the shielding ring, a third heat conducting pad contacting the shielding ring, the insulating ring contacting the third heat conducting pad, and the first heat conducting pad, so as to perform controllable warming to the focus ring.

Abstract: A method for etching a conductive layer through a mask with wider and narrower features is provided. A steady state etch gas is flowed. A steady state RF power is provided to form a plasma from the etch gas. A pulsed bias voltage is provided during the steady state etch gas flow, wherein the pulsed bias voltage has a frequency between 1 to 10,000 Hz. Wider and narrower features are etched into the conductive layer using the plasma formed from the etch gas.

Abstract: A method for etching features of different aspect ratios in a tungsten containing layer is provided. An etch gas is provided containing a tungsten etch component and a deposition component. A plasma is formed from the provided etch gas. A tungsten containing layer patterned with wide and narrow features is etched with the provided plasma.

Abstract: A plasma reactor for processing a workpiece such as a semiconductor wafer has a housing defining a process chamber, a workpiece support configured to support a workpiece within the chamber during processing and comprising a plasma bias power electrode. The reactor further includes plural gas sources containing different gas species, plural process gas inlets and an array of valves capable of coupling any of said plural gas sources to any of said plural process gas inlets. The reactor also includes a controller governing said array of valves and is programmed to change the flow rates of gases through said inlets over time. A ceiling plasma source power electrode of the reactor has plural gas injection zones coupled to the respective process gas inlets. In a preferred embodiment, the plural gas sources comprise supplies containing, respectively, fluorocarbon or fluorohydrocarbon species with respectively different ratios of carbon and fluorine chemistries.

Abstract: A method for etching a conductive layer through a mask with wider and narrower features is provided. A steady state etch gas is flowed. A steady state RF power is provided to form a plasma from the etch gas. A pulsed bias voltage is provided during the steady state etch gas flow, wherein the pulsed bias voltage has a frequency between 1 to 10,000 Hz. Wider and narrower features are etched into the conductive layer using the plasma formed from the etch gas.

Abstract: A method for etching features of different aspect ratios in a tungsten containing layer is provided. An etch gas is provided containing a tungsten etch component and a deposition component. A plasma is formed from the provided etch gas. A tungsten containing layer patterned with wide and narrow features is etched with the provided plasma.

Abstract: A method for etching features of different aspect ratios in a conductive layer is provided. The method comprises: depositing over the conductive layer with an aspect ratio dependent deposition; etching features into the conductive layer with an aspect ratio dependent etching of the conductive layer; and repeating the depositing and the etching at least once.

Abstract: A plasma etch process etches high aspect ratio openings in a dielectric film on a workpiece in a reactor having a ceiling electrode overlying the workpiece and an electrostatic chuck supporting the workpiece. The process includes injecting a polymerizing etch process gas through an annular zone of gas injection orifices in the ceiling electrode, and evacuating gas from the reactor through a pumping annulus surrounding an edge of the workpiece. The high aspect ratio openings are etched in the dielectric film with etch species derived from the etch process gas while depositing a polymer derived from the etch process gas onto the workpiece, by generating a plasma in the reactor by applying VHF source power and/or HF and/or LF bias power to the electrodes at the ceiling and/or the electrostatic chuck.

Abstract: A plasma etch process for etching high aspect ratio openings in a dielectric film on a workpiece is carried out in a reactor having a ceiling electrode overlying the workpiece and an electrostatic chuck supporting the workpiece. The process includes injecting a first polymerizing etch process gas through a radially inward one of plural concentric gas injection zones in the ceiling electrode and injecting a second polymerizing etch process gas through a radially outward one of the plural concentric gas injection zones in the ceiling electrode, the compositions of the first and second process gases having first and second carbon-to-fluorine ratios that differ from one another.

Abstract: A method for etching features of different aspect ratios in a conductive layer is provided. The method comprises: depositing over the conductive layer with an aspect ratio dependent deposition; etching features into the conductive layer with an aspect ratio dependent etching of the conductive layer; and repeating the depositing and the etching at least once.

Abstract: A method of opening a carbon-based hardmask layer composed of amorphous carbon containing preferably at least 60% carbon and between 10 and 40% hydrogen. The hardmask is opened by plasma etching using an etching gas composed of H2, N2, and CO. The etching is preferably performed in a plasma etch reactor having an HF biased pedestal electrode and a capacitively VHF biased showerhead.

Abstract: A method of opening a carbon-based hardmask layer composed of amorphous carbon containing preferably at least 60% carbon and between 10 and 40% hydrogen. The hardmask is opened by plasma etching using an etching gas composed of H2, N2, and CO. The etching is preferably performed in a plasma etch reactor having an HF biased pedestal electrode and a capacitively VHF biased showerhead.

Abstract: A plasma etch process includes injecting process gases with different compositions of chemical species through different radial gas injection zones of an overhead electrode to establish a desired distribution of chemical species among the plural gas injection zones.

Abstract: Apparatus for plasma etching a layer of material upon a substrate comprising an anode having a first region protruding from a second region, wherein the second region defines a plane and the first region extends from said plane. In one embodiment, at least one solenoid is disposed near the apparatus to magnetize the plasma.

Abstract: A plasma etch process etches high aspect ratio openings in a dielectric film on a workpiece in a reactor having a ceiling electrode overlying the workpiece and an electrostatic chuck supporting the workpiece. The process includes injecting a polymerizing etch process gas through an annular zone of gas injection orifices in the ceiling electrode, and evacuating gas from the reactor through a pumping annulus surrounding an edge of the workpiece. The high aspect ratio openings are etched in the dielectric film with etch species derived from the etch process gas while depositing a polymer derived from the etch process gas onto the workpiece, by generating a plasma in the reactor by applying VHF source power and/or HF and/or LF bias power to the electrodes at the ceiling and/or the electrostatic chuck.

Abstract: A plasma etch process for etching high aspect ratio openings in a dielectric film on a workpiece is carried out in a reactor having a ceiling electrode overlying the workpiece and an electrostatic chuck supporting the workpiece. The process includes injecting a polymerizing etch process gas through at least one of plural concentric gas injection zones of the ceiling electrode and injecting an inert diluent gas through at least a selected one of the plural gas injection zones of the ceiling electrode and apportioning respective flow rates of the diluent gas through respective ones of the gas injection zones in accordance with the distribution among corresponding concentric zones of the workpiece of etch profile tapering.

Abstract: A plasma etch process for etching a workpiece is carried out in a plasma reactor having a ceiling electrode overlying the process region with plural concentric gas injection zones. The process includes injecting process gases with different compositions of chemical species through different ones of the gas injection zones to establish a distribution of chemical species among the plural gas injection zones. The process gases include fluorine-rich polymerizing etch gases that promote a high etch rate, carbon-rich polymerizing etch gases that promote a high polymer deposition rate, polymer management gases (e.g., oxygen or nitrogen) that retard polymer deposition rate and an inert diluent gas that reduces etch profile tapering.

Abstract: A plasma reactor for processing a workpiece such as a semiconductor wafer has a housing defining a process chamber, a workpiece support configured to support a workpiece within the chamber during processing and comprising a plasma bias power electrode. The reactor further includes plural gas sources containing different gas species, plural process gas inlets and an array of valves capable of coupling any of said plural gas sources to any of said plural process gas inlets. The reactor also includes a controller governing said array of valves and is programmed to change the flow rates of gases through said inlets over time. A ceiling plasma source power electrode of the reactor has plural gas injection zones coupled to the respective process gas inlets. In a preferred embodiment, the plural gas sources comprise supplies containing, respectively, fluorocarbon or fluorohydrocarbon species with respectively different ratios of carbon and fluorine chemistries.

Abstract: A plasma etch process for etching high aspect ratio openings in a dielectric film on a workpiece is carried out in a reactor having a ceiling electrode overlying the workpiece and an electrostatic chuck supporting the workpiece. The process includes injecting a first polymerizing etch process gas through a radially inward one of plural concentric gas injection zones in the ceiling electrode and injecting a second polymerizing etch process gas through a radially outward one of the plural concentric gas injection zones in the ceiling electrode, the compositions of the first and second process gases having first and second carbon-to-fluorine ratios that differ from one another.