Abstract: An unseasoned substrate support assembly includes a ceramic body and a thermally conductive base bonded to a lower surface of the ceramic body. The substrate support assembly further includes an upper surface of the ceramic body having a first portion proximate to a center of the upper surface of the ceramic body and having a first roughness profile and a second portion distal from the center of the upper surface of the ceramic body and having a second roughness profile with a lower roughness than the first roughness profile, wherein areas of the first and second portions are based on radial distances from the center of the ceramic body.

Abstract: A method of controlling distribution of a plasma parameter in a plasma reactor having an RF-driven electrode and two (or more) counter electrodes opposite the RF driven electrode and facing different portions of the process zones. The method includes providing two (or more) variable reactances connected between respective ones of the counter electrodes and ground, and governing the variable reactances to change distribution of a plasma parameter such as plasma ion density or ion energy.

Abstract: A plasma reactor includes an RF-driven ceiling electrode overlying a process zone and two (or more) counter electrodes underlying the process zone and facing different portions of the process zones, two (or more) variable reactances connected between respective ones of the counter electrodes and ground, and a controller governing the variable reactances to control distribution of a plasma parameter such as plasma ion density or ion energy.

Abstract: A method of controlling distribution of a plasma parameter in a plasma reactor having an RF-driven electrode and two (or more) counter electrodes opposite the RF driven electrode and facing different portions of the process zones. The method includes providing two (or more) variable reactances connected between respective ones of the counter electrodes and ground, and governing the variable reactances to change distribution of a plasma parameter such as plasma ion density or ion energy.

Abstract: A plasma reactor includes an RF-driven wafer support electrode underlying a process zone and two (or more) counter electrodes overlying the process zone and facing different portions of the process zones, two (or more) variable reactances connected between respective ones of the counter electrodes and ground, and a controller governing the variable reactances to control distribution of a plasma parameter such as plasma ion density or ion energy.

Abstract: A plasma reactor for processing a workplace includes a reactor chamber having a ceiling and a sidewali and a workplace support facing the ceiling and defining a processing region, and a pair of concentric independently excited RF coil antennas overlying the ceiling and a side RF coil concentric with the side wall and facing the side wall below the ceiling, and being excited independently.

Abstract: A plasma reactor has an overhead multiple coil inductive plasma source with symmetric RF feeds and a symmetrical chamber exhaust with plural struts through the exhaust region providing access to a confined workplace support. A grid may be included for masking spatial effects of the struts from the processing region.

Abstract: A plasma reactor enclosure has a metallic portion and a dielectric portion of plural dielectric windows supported on the metallic portion, each of the dielectric windows extending around an axis of symmetry. Plural concentric coil antennas are disposed on an external side of the enclosure, respective ones of the coil antennas facing respective ones of the dielectric windows.

Abstract: Methods and apparatus for controlling the temperature of a substrate during processing are provided herein. In some embodiments, an apparatus for retaining and controlling substrate temperature may include a puck of dielectric material; an electrode disposed in the puck proximate a surface of the puck upon which a substrate is to be retained; and a plurality of heater elements disposed in the puck and arranged in concentric rings to provide independent temperature control zones.

Abstract: A triaxial rod assembly for providing both RF power and DC voltage to a chuck assembly that supports a workpiece in a processing chamber during a manufacturing operation. In embodiments, a rod assembly includes a center conductor to be coupled to a chuck electrode for providing DC voltage to clamp a workpiece. Concentrically surrounding the center conductor is an annular RF transmission line to be coupled to an RF powered base to provide RF power to the chuck assembly. An insulator is disposed between the center conductor and RF transmission line. Concentrically surrounding the RF transmission line is a ground plane conductor coupled to a grounded base of the chuck to provide a reference voltage relative to the DC voltage. An insulator is disposed between the RF transmission line and the ground plane conductor.

Abstract: A plasma reactor for processing a workpiece, includes a vacuum chamber defined by a sidewall and ceiling, and a workpiece support pedestal having a workpiece support surface in the chamber and facing the ceiling and including a cathode electrode. An RF power generator is coupled to the cathode electrode. Plasma distribution is controlled by an external annular inner electromagnet in a first plane overlying the workpiece support surface, an external annular outer electromagnet in a second plane overlying the workpiece support surface and having a greater diameter than the inner electromagnet, and an external annular bottom electromagnet in a third plane underlying the workpiece support surface. D.C. current supplies are connected to respective ones of the inner, outer and bottom electromagnets.

Abstract: A plasma reactor having a reactor chamber and an electrostatic chuck with a surface for holding a workpiece inside the chamber includes a backside gas pressure source coupled to the electrostatic chuck for applying a thermally conductive gas under a selected pressure into a workpiece-surface interface formed whenever a workpiece is held on the surface and an evaporator inside the electrostatic chuck and a refrigeration loop having an expansion valve for controlling flow of coolant through the evaporator. The reactor further includes a temperature sensor in the electrostatic chuck and a memory storing a schedule of changes in RF power or wafer temperature.

Abstract: An apparatus for generating uniform plasma across and beyond the peripheral edge of a substrate has a dielectric body with an upper electrode and an annular electrode embedded therein. The outer perimeter of the upper electrode overlaps the inner perimeter of the annular electrode. In one embodiment, the upper electrode and the annular electrode are electrically coupled by molybdenum vias. In one embodiment, the upper electrode is coupled to a DC power source to provide electrostatic force for chucking the substrate. In one embodiment, the upper electrode is coupled to an RF source for exciting one or more processing gasses into plasma for substrate processing.

Abstract: In a plasma reactor having a driven electrode and a counter electrode, an impedance controller connected between the counter electrode and ground includes both series sand parallel variable impedance elements that facilitate two-dimensional movement of a ground path input impedance in a complex impedance space to control spatial distribution of a plasma process parameter.

Abstract: Electrostatic chucks (ESCs) with RF and temperature uniformity are described. For example, an ESC includes a top dielectric layer. An upper metal portion is disposed below the top dielectric layer. A second dielectric layer is disposed above a plurality of pixilated resistive heaters and surrounded in part by the upper metal portion. A third dielectric layer is disposed below the second dielectric layer, with a boundary between the third dielectric layer and the second dielectric layer. A plurality of vias is disposed in the third dielectric layer. A bus power bar distribution layer is disposed below and coupled to the plurality of vias. A fourth dielectric layer is disposed below the bus bar power distribution layer, with a boundary between the fourth dielectric layer and the third dielectric layer. A metal base is disposed below the fourth dielectric layer. The metal base includes a plurality of high power heater elements housed therein.

Abstract: A method of controlling wafer temperature in a plasma reactor by obtaining the next scheduled change in RF heat load on the workpiece, and using thermal modeling to estimate respective changes in wafer backside gas pressure and in coolant flow through a wafer support pedestal that would compensate for the next scheduled change in RF heat load, and making the respective changes in the backside gas pressure or in the coolant flow prior to the time of the next scheduled change.

Abstract: Embodiments of the present invention provide a plasma chamber design that allows extremely symmetrical electrical, thermal, and gas flow conductance through the chamber. By providing such symmetry, plasma formed within the chamber naturally has improved uniformity across the surface of a substrate disposed in a processing region of the chamber. Further, other chamber additions, such as providing the ability to manipulate the gap between upper and lower electrodes as well as between a gas inlet and a substrate being processed, allows better control of plasma processing and uniformity as compared to conventional systems.

Abstract: A plasma reactor for processing a workpiece includes a reactor chamber, an electrostatic chuck within the chamber having a top surface for supporting a workpiece and having indentations in the top surface that form enclosed gas flow channels whenever covered by a workpiece resting on the top surface. The reactor further includes thermal control apparatus thermally coupled to the electrostatic chuck, an RF plasma bias power generator coupled to apply RF power to the electrostatic chuck, a pressurized gas supply of a thermally conductive gas, a controllable gas valve coupling the pressurized gas supply to the indentations to facilitate filling the channels with the thermally conductive gas for heat transfer between a backside of a workpiece and the electrostatic chuck at a heat transfer rate that is a function of the pressure against the backside of the workpiece of the thermally conductive gas.

Abstract: A method of processing a workpiece in a plasma reactor having an electrostatic chuck for supporting the workpiece within a reactor chamber, the method including circulating a coolant through a refrigeration loop that includes an evaporator inside the electrostatic chuck, while pressurizing a workpiece-to-chuck interface with a thermally conductive gas, sensing conditions in the chamber including temperature near the workpiece and simulating heat flow through the electrostatic chuck in a thermal model of the chuck based upon the conditions.

Abstract: Embodiments of electrostatic chucks are provided herein. In some embodiments, an electrostatic chuck may include a body having a notched upper peripheral edge, defined by a first surface perpendicular to a body sidewall and a stepped second surface disposed between the first surface and a body upper surface, and a plurality of holes disposed through the body along the first surface; a plurality of fasteners disposed through the plurality of holes to couple the body to a base disposed beneath the body; a dielectric member disposed above the body upper surface to electrostatically retain a substrate; an insulator ring disposed about the body within the notched upper peripheral edge and having a stepped inner sidewall that mates with the stepped second surface to define a non-linear interface therebetween; and an edge ring disposed over the insulator ring, the non-linear interface limiting arcing between the edge ring and the fastener.