Abstract: A method for etching a substrate includes performing, in a plasma chamber, a first etch of a substrate material using a plasma etch process. The first etch forms features to a first depth in the material. Following the first etch, the method includes performing, in the plasma chamber without removing the substrate from the chamber, an atomic layer passivation (ALP) process to deposit a conformal film of passivation over the mask and the features formed during the first etch. The ALP process uses a vapor from a liquid precursor to form passivation over the features and the mask. The method further includes performing, in the plasma chamber, a second etch of the material using the plasma etch process. The conformal film of passivation is configured to protect the mask and sidewalls of the features during the second etch. A plasma processing system also is described.

Abstract: An edge ring assembly for a plasma processing chamber is provided, including: an edge ring configured to surround an electrostatic chuck (ESC) that is configured for electrical connection to a first RF power supply, the ESC having a top surface for supporting a substrate and an annular step surrounding the top surface, the annular step defining an annular shelf that is lower than the top surface; an annular electrode disposed below the edge ring in the annular step and above the annular shelf; a dielectric ring disposed below the annular electrode for isolating the annular electrode from the ESC, the dielectric ring positioned in the annular step over the annular shelf; and, a plurality of insulated connectors disposed through the ESC and through the dielectric ring, each of the plurality of insulated connectors providing electrical connection between a second RF power supply and the annular electrode.

Abstract: A method for processing a stack with a carbon based patterned mask is provided. The stack is placed in an etch chamber. A silicon oxide layer is deposited by atomic layer deposition over the carbon based patterned mask by providing a plurality of cycles, wherein each of the cycles of the plurality of cycles, comprises providing a silicon precursor deposition phase, comprising flowing an atomic layer deposition precursor gas into the etch chamber, where the atomic layer deposition precursor gas is deposited while plasmaless and stopping the flow of the atomic layer deposition precursor gas and providing an oxygen deposition phase, comprising flowing ozone gas into the etch chamber, wherein the ozone gas binds with the deposited precursor gas while plasmaless and stopping the flow of ozone gas into the etch chamber. Part of the silicon oxide layer is etched. The stack is removed from the etch chamber.

Abstract: A method for etching an etch layer in a stack over a substrate wherein the etch layer is under a mask layer which is under a patterned organic mask is provided. The stack and substrate is placed on a support in the plasma chamber. A silicon based layer is deposited in situ over the stack. The silicon based layer is etched to form silicon based sidewalls or spacers on sides of the patterned organic mask. The mask layer is selectively etched with respect to the silicon based sidewalls or spacers, wherein the selectively etching the mask layer undercuts the silicon based sidewalls or spacers. The etch layer is selectively etched with respect to the mask layer. The stack and substrate are removed from the support and the plasma chamber.

Abstract: A method for etching an etch layer in a stack over a substrate wherein the etch layer is under a mask layer which is under a patterned organic mask is provided. The stack and substrate is placed on a support in the plasma chamber. A silicon based layer is deposited in situ over the stack. The silicon based layer is etched to form silicon based sidewalls or spacers on sides of the patterned organic mask. The mask layer is selectively etched with respect to the silicon based sidewalls or spacers, wherein the selectively etching the mask layer undercuts the silicon based sidewalls or spacers. The etch layer is selectively etched with respect to the mask layer. The stack and substrate are removed from the support and the plasma chamber.

Abstract: An edge ring assembly for a plasma processing chamber is provided, including: an edge ring configured to surround an electrostatic chuck (ESC) that is configured for electrical connection to a first RF power supply, the ESC having a top surface for supporting a substrate and an annular step surrounding the top surface, the annular step defining an annular shelf that is lower than the top surface; an annular electrode disposed below the edge ring in the annular step and above the annular shelf; a dielectric ring disposed below the annular electrode for isolating the annular electrode from the ESC, the dielectric ring positioned in the annular step over the annular shelf; and, a plurality of insulated connectors disposed through the ESC and through the dielectric ring, each of the plurality of insulated connectors providing electrical connection between a second RF power supply and the annular electrode.

Abstract: A method for etching features into a silicon containing etch layer is provided. The etch layer is placed into a plasma processing chamber. An etch gas is flowed into the plasma processing chamber. The etch gas is formed into an etch plasma, wherein the etch plasma etches features into the silicon containing layer leaving silicon containing residue. The flow of etch gas into the plasma processing chamber is stopped. A dry clean gas is flowed into the plasma processing chamber, wherein the dry clean gas comprises NH3 and NF3. The dry clean gas is formed into a plasma, wherein the silicon containing residue is exposed to the dry clean gas plasma, and wherein at least some or all of the silicon containing residue is formed into ammonium containing compounds. The flow of the dry clean gas is stopped. The ammonium compounds are sublimated from the films.

Abstract: A method for forming features in a polysilicon layer is provided. A hardmask layer is formed over the polysilicon layer. A photoresist mask is formed over the hardmask layer. The hardmask layer is etched through the photoresist mask to form a patterned hardmask. The patterned hardmask is trimmed by providing a non-carbon containing trim gas comprising oxygen and a fluorine containing compound, forming a plasma from the trim gas, and trimming the hardmask. Features are etched into the polysilicon layer through the hardmask.

Abstract: A method for forming features in a polysilicon layer is provided. A hardmask layer is formed over the polysilicon layer. A photoresist mask is formed over the hardmask layer. The hardmask layer is etched through the photoresist mask to form a patterned hardmask. The patterned hardmask is trimmed by providing a non-carbon containing trim gas comprising oxygen and a fluorine containing compound, forming a plasma from the trim gas, and trimming the hardmask. Features are etched into the polysilicon layer through the hardmask.

Abstract: A method for forming features in a polysilicon layer is provided. A hardmask layer is formed over the polysilicon layer. A photoresist mask is formed over the hardmask layer. The hardmask layer is etched through the photoresist mask to form a patterned hardmask. The patterned hardmask is trimmed by providing a non-carbon containing trim gas comprising oxygen and a fluorine containing compound, forming a plasma from the trim gas, and trimming the hardmask. Features are etched into the polysilicon layer through the hardmask.

Abstract: A method for forming features in a polysilicon layer is provided. A hardmask layer is formed over the polysilicon layer. A photoresist mask is formed over the hardmask layer. The hardmask layer is etched through the photoresist mask to form a patterned hardmask. The patterned hardmask is trimmed by providing a non-carbon containing trim gas comprising oxygen and a fluorine containing compound, forming a plasma from the trim gas, and trimming the hardmask. Features are etched into the polysilicon layer through the hardmask.

Abstract: An apparatus and method for etching a feature in a wafer with improved depth control and reproducibility is described. The feature is etched at a first etching rate and then at a second etching rate, which is slower than the first etching rate. An optical end point device is used to determine the etching depth and etching is stopped so that the feature has the desired depth. Two different etching rates provides high throughput with good depth control and reproducibility. The apparatus includes an etching tool in which a chuck holds the wafer to be etched. An optical end point device is positioned to measure the feature etch depth. An electronic controller communicates with the optical end point device and the etching tool to control the tool to reduce the etch rate part way through etching the feature and to stop the etching tool, so that that the feature is etched to the desired depth.

Abstract: An etch processor for etching a wafer includes a chuck for holding the wafer and a temperature sensor reporting a temperature of the wafer. The chuck includes a heater controlled by a temperature control system. The temperature sensor is operatively coupled to the temperature control system to maintain the temperature of the chuck at a selectable setpoint temperature. A first setpoint temperature and a second setpoint temperature are selected. The wafer is placed on the chuck and set to the first setpoint temperature. The wafer is then processed for a first period of time at the first setpoint temperature and for a second period of time at the second setpoint temperature.

Abstract: An apparatus and method for etching a feature in a wafer with improved depth control and reproducibility is described. The feature is etched at a first etching rate and then at a second etching rate, which is slower than the first etching rate. An optical end point device is used to determine the etching depth and etching is stopped so that the feature has the desired depth. Two different etching rates provides high throughput with good depth control and reproducibility. The apparatus includes an etching tool in which a chuck holds the wafer to be etched. An optical end point device is positioned to measure the feature etch depth. An electronic controller communicates with the optical end point device and the etching tool to control the tool to reduce the etch rate part way through etching the feature and to stop the etching tool, so that that the feature is etched to the desired depth.

Abstract: An etch processor for etching a wafer includes a chuck for holding the wafer and a temperature sensor reporting a temperature of the wafer. The chuck includes a heater controlled by a temperature control system. The temperature sensor is operatively coupled to the temperature control system to maintain the temperature of the chuck at a selectable setpoint temperature. A first setpoint temperature and a second setpoint temperature are selected. The wafer is placed on the chuck and set to the first setpoint temperature. The wafer is then processed for a first period of time at the first setpoint temperature and for a second period of time at the second setpoint temperature.