Abstract: A direct (DC) voltage is applied to an electrode at a voltage value to clamp a workpiece to an electrostatic chuck in a processing chamber. The electrode is embedded into the electrostatic chuck. An electrostatic chuck current through the electrode at the DC voltage is measured. A DC self bias induced on the workpiece by a plasma is determined based on the electrostatic chuck current and the applied voltage.

Abstract: A method for etching a dielectric layer disposed on a substrate is provided. The method includes de-chucking the substrate from an electrostatic chuck in an etching processing chamber, and cyclically etching the dielectric layer while the substrate is de-chucked from the electrostatic chuck. The cyclical etching includes remotely generating a plasma in an etching gas mixture supplied into the etching processing chamber to etch the dielectric layer disposed on the substrate at a first temperature. Etching the dielectric layer generates etch byproducts. The cyclical etching also includes vertically moving the substrate towards a gas distribution plate in the etching processing chamber, and flowing a sublimation gas from the gas distribution plate towards the substrate to sublimate the etch byproducts. The sublimation is performed at a second temperature, wherein the second temperature is greater than the first temperature.

Abstract: A method for etching a dielectric layer disposed on a substrate is provided. The method includes de-chucking the substrate from an electrostatic chuck in an etching processing chamber, and cyclically etching the dielectric layer while the substrate is de-chucked from the electrostatic chuck. The cyclical etching includes remotely generating a plasma in an etching gas mixture supplied into the etching processing chamber to etch the dielectric layer disposed on the substrate at a first temperature. Etching the dielectric layer generates etch byproducts. The cyclical etching also includes vertically moving the substrate towards a gas distribution plate in the etching processing chamber, and flowing a sublimation gas from the gas distribution plate towards the substrate to sublimate the etch byproducts. The sublimation is performed at a second temperature, wherein the second temperature is greater than the first temperature.

Abstract: A direct (DC) voltage is applied to an electrode at a voltage value to clamp a workpiece to an electrostatic chuck in a processing chamber. The electrode is embedded into the electrostatic chuck. An electrostatic chuck current through the electrode at the DC voltage is measured. A DC self bias induced on the workpiece by a plasma is determined based on the electrostatic chuck current and the applied voltage.

Abstract: A method of etching silicon oxide from a trench is described which allows more homogeneous etch rates across a varying pattern on a patterned substrate. The method also provides a more rectilinear profile following the etch process. Methods include a sequential exposure of gapfill silicon oxide. The gapfill silicon oxide is exposed to a local plasma treatment prior to a remote-plasma dry etch which may produce salt by-product on the surface. The local plasma treatment has been found to condition the gapfill silicon oxide such that the etch process proceeds at a more even rate within each trench and across multiple trenches. The salt by-product may be removed by raising the temperature in a subsequent sublimation step.

Abstract: Embodiments of sensor devices for characterizing magnetic fields formed in substrate processing systems and methods of use thereof are provided herein. In some embodiments, an apparatus for characterizing a magnetic field in a substrate processing system may include a carrier having a form substantially similar to a substrate to be processed in the substrate processing system. One or more magnetic sensors are disposed on the carrier for measuring a magnitude of a magnetic field formed in the processing system in an x-, y-, and z-direction. A microprocessor is coupled to the one or more magnetic sensors to sample data representative of the magnitude of the magnetic field in the x-, y-, and z-directions proximate a position of each sensor. A memory device is coupled to the microprocessor for storing the sampled data. A power source is provided to supply power to each magnetic sensor and the microprocessor.

Abstract: Embodiments of sensor devices for characterizing magnetic fields formed in substrate processing systems and methods of use thereof are provided herein. In some embodiments, an apparatus for characterizing a magnetic field in a substrate processing system may include a carrier having a form substantially similar to a substrate to be processed in the substrate processing system. One or more magnetic sensors are disposed on the carrier for measuring a magnitude of a magnetic field formed in the processing system in an x-, y-, and z-direction. A microprocessor is coupled to the one or more magnetic sensors to sample data representative of the magnitude of the magnetic field in the x-, y-, and z-directions proximate a position of each sensor. A memory device is coupled to the microprocessor for storing the sampled data. A power source is provided to supply power to each magnetic sensor and the microprocessor.