Abstract: Methods and apparatus reduce chucking abnormalities for electrostatic chucks by ensuring proper planarizing of ceramic surfaces of the electrostatic chuck. In some embodiments, a method for planarizing an upper ceramic surface of an electrostatic chuck assembly may comprise placing the electrostatic chuck assembly in a first planarizing apparatus, altering an upper ceramic surface of the electrostatic chuck assembly, and halting the altering of the upper ceramic surface of the electrostatic chuck assembly when an Sa parameter is less than approximately 0.1 microns, an Sdr parameter is less than approximately 2.5 percent, an Sz parameter is less than approximately 10 microns for any given area of approximately 10 mm2 of the upper ceramic surface, or a pit-porosity depth parameter of greater than 1 micron is less than approximately 0.1 percent of area of the upper ceramic surface.

Abstract: Substrate temperature control apparatus and electronic device manufacturing systems provide pixelated light-based heating to a substrate in a process chamber. A substrate holder in the process chamber may include a baseplate. The baseplate has a top surface that may have a plurality of cavities and a plurality of grooves connected to the cavities. Optical fibers may be received in the grooves such that each cavity has a respective optical fiber terminating therein to transfer light thereto. Some or all of the cavities may have an epoxy optical diffuser disposed therein to diffuse light provided by the optical fiber. A ceramic plate upon which a substrate may be placed may be bonded to the baseplate. A thermal spreader plate may optionally be provided between the baseplate and the ceramic plate. Methods of controlling temperature across a substrate holder in an electronic device manufacturing system are also provided, as are other aspects.

Abstract: Implementations described herein provide a pixelated substrate support assembly which enables both lateral and azimuthal tuning of the heat transfer between an electrostatic chuck and a cooling base comprising the substrate support assembly, which in turn, allows both lateral and azimuthal tuning of a substrate processed on the substrate support assembly. A processing chamber having a pixelated substrate support assembly and method for processing a substrate using a pixelated substrate support assembly are also provided.

Abstract: An electrostatic chuck is described with external flow adjustments for improved temperature distribution. In one example, a method for adjusting coolant flow in an electrostatic chuck includes heating a dielectric puck, the dielectric puck being for electrostatically gripping a silicon wafer. Heat is detected at a plurality of locations on a top surface of the dielectric puck, the locations each being thermally coupled to at least one of a plurality of coolant chambers of the electrostatic chuck. A plurality of valves are adjusted to control coolant flow into the coolant chambers based on the detected heat.

Abstract: Substrate temperature control apparatus including groove-routed optical fibers. Substrate temperature control apparatus includes upper and lower members including grooves in one or both, and a plurality of optical fibers routed in the grooves. In one embodiment, the optical fibers are adapted to provide light-based pixelated heating. In another embodiment, embedded optical temperature sensors are adapted to provide temperature measurement. Substrate temperature control systems, electronic device processing systems, and methods including groove-routed optical fiber temperature control and measurement are described, as are numerous other aspects.

Abstract: A control system that includes deflection sensors which can control clamping forces applied by electrostatic chucks, and related methods are disclosed. By using a sensor to determine a deflection of a workpiece supported by an electrostatic chuck, a control system may use the deflection measured to control a clamping force applied to the workpiece by the electrostatic chuck. The control system applies a clamping voltage to the electrostatic chuck so that the clamping force reaches and maintains a target clamping force. In this manner, the clamping force may secure the workpiece to the electrostatic chuck to enable manufacturing operations to be performed while preventing workpiece damage resulting from unnecessary higher values of the clamping force.

Abstract: An electrostatic chuck is described with external flow adjustments for improved temperature distribution. In one example, a method for adjusting coolant flow in an electrostatic chuck includes heating a dielectric puck, the dielectric puck being for electrostatically gripping a silicon wafer. Heat is detected at a plurality of locations on a top surface of the dielectric puck, the locations each being thermally coupled to at least one of a plurality of coolant chambers of the electrostatic chuck. A plurality of valves are adjusted to control coolant flow into the coolant chambers based on the detected heat.

Abstract: Substrate temperature control apparatus including optical fiber temperature control are described. Substrate temperature control apparatus includes a base, a thermal contact member proximate to the base, and a plurality of optical fibers adapted to provide light-based heating extending laterally between the base and thermal contact member. Substrate temperature control systems and electronic device processing systems and methods including optical fiber temperature control are described, as are numerous other aspects.

Abstract: A control system that includes deflection sensors which can control clamping forces applied by electrostatic chucks, and related methods are disclosed. By using a sensor to determine a deflection of a workpiece supported by an electrostatic chuck, a control system may use the deflection measured to control a clamping force applied to the workpiece by the electrostatic chuck. The control system applies a clamping voltage to the electrostatic chuck so that the clamping force reaches and maintains a target clamping force. In this manner, the clamping force may secure the workpiece to the electrostatic chuck to enable manufacturing operations to be performed while preventing workpiece damage resulting from unnecessary higher values of the clamping force.

Abstract: An electrostatic chuck is described with external flow adjustments for improved temperature distribution. In one example, an apparatus has a dielectric puck to electrostatically grip a silicon wafer. A cooling plate is fastened to and thermally coupled to the ceramic puck. A supply plenum receives coolant from an external source and a plurality of coolant chambers are thermally coupled to the cooling plate and receive coolant from the supply plenum. A return plenum is coupled to the cooling zones to exhaust coolant from the cooling zones and a plurality of flow control valves are positioned between the supply plenum and a respective one of the cooling zones to control the flow rate of coolant from the supply plenum to the cooling zones.

Abstract: A control system that includes deflection sensors which can control clamping forces applied by electrostatic chucks, and related methods are disclosed. By using a sensor to determine a deflection of a workpiece supported by an electrostatic chuck, a control system may use the deflection measured to control a clamping force applied to the workpiece by the electrostatic chuck. The control system applies a clamping voltage to the electrostatic chuck so that the clamping force reaches and maintains a target clamping force. In this manner, the clamping force may secure the workpiece to the electrostatic chuck to enable manufacturing operations to be performed while preventing workpiece damage resulting from unnecessary higher values of the clamping force.

Abstract: An electrostatic chuck is described with external flow adjustments for improved temperature distribution. In one example, an apparatus has a dielectric puck to electrostatically grip a silicon wafer. A cooling plate is fastened to and thermally coupled to the ceramic puck. A supply plenum receives coolant from an external source and a plurality of coolant chambers are thermally coupled to the cooling plate and receive coolant from the supply plenum. A return plenum is coupled to the cooling zones to exhaust coolant from the cooling zones. A plurality of adjustable orifices are positioned between the supply plenum and a respective one of the cooling zones to control the flow rate of coolant from the supply plenum to the cooling zones.

Abstract: Embodiments of the present invention generally relate to a method and apparatus for ex-situ cleaning of a chamber component. More particularly, embodiments of the present invention generally relate to a method and apparatus for endpoint detection during ex-situ cleaning of a chamber component used in a semiconductor processing chamber. In one embodiment, a system for cleaning parts disposed in a liner with a cleaning fluid is provided. The system comprises a portable cart, a liquid particle counter (LPC) carried by the portable cart, the LPC configured for detachable coupling to a fluid outlet port formed through the liner, the LPC operable to sample rinsate solution exiting the line, and a pump carried by the portable cart and configured for fluid coupling to the liner in a detachable manner, the pump operable to recirculate rinsate solution through the liner.

Abstract: Substrate temperature control apparatus and electronic device manufacturing systems provide pixelated light-based heating to a substrate in a process chamber. A substrate holder in the process chamber may include a baseplate. The baseplate has a top surface that may have a plurality of cavities and a plurality of grooves connected to the cavities. Optical fibers may be received in the grooves such that each cavity has a respective optical fiber terminating therein to transfer light thereto. Some or all of the cavities may have an epoxy optical diffuser disposed therein to diffuse light provided by the optical fiber. A ceramic plate upon which a substrate may be placed may be bonded to the baseplate. A thermal spreader plate may optionally be provided between the baseplate and the ceramic plate. Methods of controlling temperature across a substrate holder in an electronic device manufacturing system are also provided, as are other aspects.

Abstract: Substrate temperature control apparatus including groove-routed optical fibers. Substrate temperature control apparatus includes upper and lower members including grooves in one or both, and a plurality of optical fibers routed in the grooves. In one embodiment, the optical fibers are adapted to provide light-based pixelated heating. In another embodiment, embedded optical temperature sensors are adapted to provide temperature measurement. Substrate temperature control systems, electronic device processing systems, and methods including groove-routed optical fiber temperature control and measurement are described, as are numerous other aspects.

Abstract: Substrate temperature control apparatus including optical fiber temperature control are described. Substrate temperature control apparatus includes a base, a thermal contact member proximate to the base, and a plurality of optical fibers adapted to provide light-based heating extending laterally between the base and thermal contact member. Substrate temperature control systems and electronic device processing systems and methods including optical fiber temperature control are described, as are numerous other aspects.

Abstract: Electrostatic chucks with variable pixelated heating are described. For example, an electrostatic chuck (ESC) includes a ceramic plate having a front surface and a back surface, the front surface for supporting a wafer or substrate. A base is coupled to the back surface of the ceramic plate. A light carrying medium is disposed in the base, the light carrying medium configured to provide pixelated light-based heating capability for the ESC.

Abstract: An electrostatic chuck is described with external flow adjustments for improved temperature distribution. In one example, an apparatus has a dielectric puck to electrostatically grip a silicon wafer. A cooling plate is fastened to and thermally coupled to the ceramic puck. A supply plenum receives coolant from an external source and a plurality of coolant chambers are thermally coupled to the cooling plate and receive coolant from the supply plenum. A return plenum is coupled to the cooling zones to exhaust coolant from the cooling zones and a plurality of flow control valves are positioned between the supply plenum and a respective one of the cooling zones to control the flow rate of coolant from the supply plenum to the cooling zones.

Abstract: An electrostatic chuck is described with external flow adjustments for improved temperature distribution. In one example, an apparatus has a dielectric puck to electrostatically grip a silicon wafer. A cooling plate is fastened to and thermally coupled to the ceramic puck. A supply plenum receives coolant from an external source and a plurality of coolant chambers are thermally coupled to the cooling plate and receive coolant from the supply plenum. A return plenum is coupled to the cooling zones to exhaust coolant from the cooling zones. A plurality of adjustable orifices are positioned between the supply plenum and a respective one of the cooling zones to control the flow rate of coolant from the supply plenum to the cooling zones.

Abstract: A control system that includes deflection sensors which can control clamping forces applied by electrostatic chucks, and related methods are disclosed. By using a sensor to determine a deflection of a workpiece supported by an electrostatic chuck, a control system may use the deflection measured to control a clamping force applied to the workpiece by the electrostatic chuck. The control system applies a clamping voltage to the electrostatic chuck so that the clamping force reaches and maintains a target clamping force. In this manner, the clamping force may secure the workpiece to the electrostatic chuck to enable manufacturing operations to be performed while preventing workpiece damage resulting from unnecessary higher values of the clamping force.