Abstract: A pulsed plasma system with pulsed reaction gas replenish for etching semiconductor structures is described. In an embodiment, a portion of a sample is removed by applying a pulsed plasma etch process. The pulsed plasma etch process comprises a plurality of duty cycles, wherein each duty cycle represents the combination of an ON state and an OFF state of a plasma. The plasma is generated from a reaction gas, wherein the reaction gas is replenished during the OFF state of the plasma, but not during the ON state. In another embodiment, a first portion of a sample is removed by applying a continuous plasma etch process. The continuous plasma etch process is then terminated and a second portion of the sample is removed by applying a pulsed plasma etch process having pulsed reaction gas replenish.

Abstract: A pulsed plasma system for etching semiconductor structures is described. In one embodiment, a portion of a sample is removed by applying a pulsed plasma process, wherein the pulsed plasma process comprises a plurality of duty cycles. The ON state of a duty cycle is of a duration sufficiently short to substantially inhibit micro-loading in a reaction region adjacent to the sample, while the OFF state of the duty cycle is of a duration sufficiently long to substantially enable removal of a set of etch by-products from the reaction region. In another embodiment, a first portion of a sample is removed by applying a continuous plasma process. The continuous plasma process is then terminated and a second portion of the sample is removed by applying a pulsed plasma process.

Abstract: A method of processing a workpiece in the chamber of a plasma reactor includes introducing a process gas into the chamber, simultaneously (a) capacitively coupling VHF plasma source power into a process region of the chamber that overlies the wafer, and (b) inductively coupling RF plasma source power into the process region, and controlling plasma ion density by controlling the effective frequency of the VHF source power. In a preferred embodiment, the step of coupling VHF source power is performed by coupling VHF source power from different generators having different VHF frequencies, and the step of controlling the effective frequency is performed by controlling the ratio of power coupled by the different generators.

Abstract: Embodiments of field enhanced inductively coupled plasma reactors and methods of use of same are provided herein. In some embodiments, a field enhanced inductively coupled plasma processing system may include a process chamber having a dielectric lid and a plasma source assembly disposed above the dielectric lid. The plasma source assembly includes one or more coils configured to inductively couple RF energy into the process chamber to form and maintain a plasma therein, one or more electrodes configured to capacitively couple RF energy into the process chamber to form the plasma therein, wherein the one or more electrodes are electrically coupled to one of the one or more coils, and an RF generator coupled to the one or more inductive coils and the one or more electrodes. In some embodiments, a heater element may be disposed between the dielectric lid and the plasma source assembly.

Abstract: A plasma reactor for processing a workpiece includes a reactor chamber and a workpiece support within the chamber, the chamber having a ceiling facing the workpiece support, a capacitively coupled plasma source power applicator comprising a source power electrode at one of: (a) the ceiling (b) the workpiece support, and plural VHF power generators of different fixed frequencies coupled to the capacitively coupled source power applicator, and a controller for independently controlling the power output levels of the plural VHF generators so as to control an effective VHF frequency applied to the source power electrode. In a preferred embodiment, the reactor further includes a plasma bias power applicator that includes a bias power electrode in the workpiece support and one or more RF bias power generators of different frequencies coupled to the plasma bias power applicator.

Abstract: A gas distribution assembly for the ceiling of a plasma reactor includes a center fed hub and an equal path length distribution gas manifold underlying the center fed hub.

Abstract: A passivation species precursor gas is furnished to an inner zone at a first flow rate, while flowing an etchant species precursor gas an annular intermediate zone at a second flow rate. Radial distribution of etch rate is controlled by the ratio of the first and second flow rates. The radial distribution of etch critical dimension bias on the wafer is controlled by flow rate of passivation gas to the wafer edge.

Abstract: A shielded lid heater lid heater suitable for use with a plasma processing chamber, a plasma processing chamber having a shielded lid heater and a method for plasma processing are provided. The method and apparatus enhances positional control of plasma location within a plasma processing chamber, and may be utilized in etch, deposition, implant, and thermal processing systems, among other applications where the control of plasma location is desirable. In one embodiment, a shielded lid heater is provided that includes an aluminum base and RF shield sandwiching a heater element.

Abstract: A flow equalizer plate is provided for use in a substrate process chamber. The flow equalizer plate has an annular shape with a flow obstructing inner region, and a perforated outer region that permits the passage of a processing gas, but retains specific elements in the processing gas, such as active radicals or ions. The inner and outer regions have varying radial widths so as to balance a flow of processing gas over a surface of a substrate. In certain embodiments, the flow equalizer plate may be utilized to correct chamber flow asymmetries due to a lateral offset of an exhaust port relative to a center line of a substrate support between the process volume and the exhaust port.

Abstract: Embodiments of the present invention provide apparatus and method for processing a substrate with increased uniformity. One embodiment of the present invention provides an apparatus for processing a substrate. The apparatus comprises a chamber body defining a processing volume, a substrate support disposed in the processing volume, a showerhead disposed in the processing volume opposite to the substrate support, and a plasma generation assembly configured to ignite a plasma from the processing gases in the processing gas in the processing volume. The showerhead is configured to provide one or more processing gases to the processing volume. The showerhead has two or more distribution zones each independently controllable.

Abstract: In a plasma etch process, critical dimension (CD), CD bias and CD bias microloading are controlled independently of plasma process conditions or parameters, such as RF power levels, pressure and gas flow rate, by depressing or elevating the workpiece support pedestal to vary the gap between the workpiece and the chamber ceiling facing the workpiece, using an axially adjustable workpiece support.

Abstract: A method of processing a wafer in a plasma, in which target values of two different plasma process parameters are simultaneously realized under predetermined process conditions by setting respective power levels of VHF and HF power simultaneously coupled to the wafer to respective optimum levels.

Abstract: The disclosure concerns a wafer support for use in a plasma reactor chamber, in which the wafer support has a wafer edge gas injector adjacent and surrounding the wafer edge.

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: The disclosure concerns a method of processing a workpiece or in a plasma reactor chamber, using independent gas injection at the wafer edge.

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: A pulsed plasma system with pulsed reaction gas replenish for etching semiconductor structures is described. In an embodiment, a portion of a sample is removed by applying a pulsed plasma etch process. The pulsed plasma etch process comprises a plurality of duty cycles, wherein each duty cycle represents the combination of an ON state and an OFF state of a plasma. The plasma is generated from a reaction gas, wherein the reaction gas is replenished during the OFF state of the plasma, but not during the ON state. In another embodiment, a first portion of a sample is removed by applying a continuous plasma etch process. The continuous plasma etch process is then terminated and a second portion of the sample is removed by applying a pulsed plasma etch process having pulsed reaction gas replenish.

Abstract: A pulsed plasma system for etching semiconductor structures is described. In one embodiment, a portion of a sample is removed by applying a pulsed plasma process, wherein the pulsed plasma process comprises a plurality of duty cycles. The ON state of a duty cycle is of a duration sufficiently short to substantially inhibit micro-loading in a reaction region adjacent to the sample, while the OFF state of the duty cycle is of a duration sufficiently long to substantially enable removal of a set of etch by-products from the reaction region. In another embodiment, a first portion of a sample is removed by applying a continuous plasma process. The continuous plasma process is then terminated and a second portion of the sample is removed by applying a pulsed plasma process.

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 process is provided for removing polymer from a backside of a workpiece and/or photoresist from a front side of the workpiece. For backside polymer removal, the wafer is positioned near the ceiling to above a localized or remote plasma source having a side outlet through the sidewall of the chamber, and backside polymer is removed by rotating the workpiece while flowing plasma by-products from the side outlet to the wafer backside. For front side photoresist removal, the wafer is positioned away from the ceiling and below the side outlet of the localized plasma source, and front side photoresist is remove by rotating the workpiece while flowing plasma by-products from the side outlet to the wafer front side.