Abstract: A method of making a Si containing gas distribution member for a semiconductor plasma processing chamber comprises forming a carbon member into an internal cavity structure of the Si containing gas distribution member. The method includes depositing Si containing material on the formed carbon member such that the Si containing material forms a shell around the formed carbon member. The Si containing shell is machined into the structure of the Si containing gas distribution member wherein the machining forms gas inlet and outlet holes exposing a portion of the formed carbon member in an interior region of the Si containing gas distribution member.

Abstract: A method of making a Si containing gas distribution member for a semiconductor plasma processing chamber comprises forming a carbon member into an internal cavity structure of the Si containing gas distribution member. The method includes depositing Si containing material on the formed carbon member such that the Si containing material forms a shell around the formed carbon member. The Si containing shell is machined into the structure of the Si containing gas distribution member wherein the machining forms gas inlet and outlet holes exposing a portion of the formed carbon member in an interior region of the Si containing gas distribution member.

Abstract: A method of making a Si containing gas distribution member for a semiconductor plasma processing chamber comprises forming a carbon member into an internal cavity structure of the Si containing gas distribution member. The method includes depositing Si containing material on the formed carbon member such that the Si containing material forms a shell around the formed carbon member. The Si containing shell is machined into the structure of the Si containing gas distribution member wherein the machining forms gas inlet and outlet holes exposing a portion of the formed carbon member in an interior region of the Si containing gas distribution member.

Abstract: An invention is provided for a platen for use in a CMP system. The platen includes an inner set of pressure sub regions capable of providing pressure to a polishing pad disposed above the platen. Each of the inner pressure sub regions is disposed below a wafer and within a circumference of the wafer. In addition, the platen includes an outer set of pressure sub regions capable of providing pressure to a polishing pad. Each of the outer set of pressure sub regions is disposed below the wafer and outside the circumference of the wafer. In this manner, the outer set of pressure sub regions is capable of shaping the polishing pad to achieve a particular removal rate.

Abstract: An invention is provided for a chemical mechanical planarization apparatus for processing 300 millimeter wafers. The CMP apparatus includes a polishing belt having a belt tension in a range of about 3000 lbs to 4000 lbs. In addition, a platen is disposed below the polishing belt at a positive platen height. The platen includes at least three air pressure zones, with each air pressure zone being capable of providing air pressure to a backside of the polishing belt. The platen can include, for example, eight air pressure zones. In this aspect, a second air pressure zone adjacent to a first outermost air pressure zone provides an air pressure in a range of about 30 psi to 50 psi, such as about 34 psi. In addition, a third air pressure zone a fourth pressure zone can each provide an air pressure in a range of about 4 psi to 13 psi, such as about 7 psi. In this aspect, the remaining air pressure zones can be set to 0 psi, which conserves fluid consumption.

Abstract: A platen is disclosed. The platen includes a support surface for supporting a portion of a linear polishing belt during a chemical mechanical polishing (CMP) operation. The platen also includes a plurality of fluid outlets oriented throughout the support surface. The orientation defines an asymmetric pattern where each of the plurality of fluid outlets is capable of outputting a controlled fluid toward an underside of the linear polishing belt.

Abstract: A platen is provided for use in a chemical mechanical planarization (CMP) system. The platen includes at least one fluid output zone having a plurality of fluid outlets, the at least one fluid output zone being disposed below a polishing pad and being capable of providing fluid pressure to the polishing pad. The platen also includes at least one fluid input zone having a plurality of fluid inlets, the at least one fluid input zone being disposed below the polishing pad and being capable of removing the fluid pressure. The platen is capable of managing fluid pressure applied to the polishing pad to achieve a particular polishing profile during a CMP operation.

Abstract: An invention is provided for a CMP apparatus that enhances removal rate uniformity. The CMP apparatus includes a polishing belt disposed below a carrier head that is capable of applying a wafer to the polishing belt. Also included is a platen disposed below the polishing belt. The platen includes a circular shim section disposed on the top surface of the platen. The circular shim section is higher than the top surface of the platen. When using this configuration, increasing pressure to the backside of the polishing belt decreases the edge removal rate of the wafer. Conversely, decreasing pressure to the backside of the polishing belt increases the edge removal rate of the wafer.

Abstract: An invention is provided for a platen for use in a CMP system. The platen includes an inner set of pressure sub regions capable of providing pressure to a polishing pad disposed above the platen. Each of the inner pressure sub regions is disposed below a wafer and within a circumference of the wafer. In addition, the platen includes an outer set of pressure sub regions capable of providing pressure to a polishing pad. Each of the outer set of pressure sub regions is disposed below the wafer and outside the circumference of the wafer. In this manner, the outer set of pressure sub regions is capable of shaping the polishing pad to achieve a particular removal rate.