Abstract: A plasma processing system for processing a substrate, is disclosed. The plasma processing system includes a single chamber, substantially azimuthally symmetric plasma processing chamber within which a plasma is both ignited and sustained for the processing. The plasma processing chamber has no separate plasma generation chamber. The plasma processing chamber has an upper end and a lower end. The plasma processing chamber includes a material that does not substantially react with the reactive gas chemistries that are delivered into the plasma processing chamber. In addition, the reactant gases that are flown into the plasma processing chamber are disclosed.

Abstract: A plasma processing system that includes a plasma processing chamber that provides enhanced control over an etch process is disclosed. The plasma processing chamber is connected to a gas flow system. The gas flow system can be employed to control the release of gases into different regions within the plasma processing chamber. In addition, the volume of the released gas, e.g., the flow rate of the gas, can be adjusted by a gas flow control mechanism. In this manner, both the position and the amount of the gas that is delivered to the plasma processing chamber can be controlled. The ability to adjust the position and the amount of gas that is released into the plasma processing chamber provides for a better control over the distribution of the neutral components. This in turn enhances control over the etching process.

Abstract: Apparatus and methods control the temperature of a wafer for chemical mechanical polishing operations. A wafer carrier has a wafer mounting surface for positioning the wafer adjacent to a thermal energy transfer unit for transferring energy relative to the wafer. A thermal energy detector is oriented adjacent to the wafer mounting surface for detecting the temperature of the wafer. A controller is responsive to the detector for controlling the supply of thermal energy relative to the thermal energy transfer unit. Embodiments include defining separate areas of the wafer, providing separate sections of the thermal energy transfer unit for each separate area, and separately detecting the temperature of each separate area to separately control the supply of thermal energy relative to the thermal energy transfer unit associated with the separate area.

Abstract: A plasma confinement arrangement for controlling the volume of a plasma while processing a substrate inside a process chamber includes a chamber within which a plasma is both ignited and sustained for processing. The chamber is defined at least in part by a wall and further includes a plasma confinement arrangement. The plasma confinement arrangement includes a magnetic array disposed around the periphery of the process chamber configured to produce a magnetic field which establishes a cusp pattern on the wall of the chamber. The cusp pattern on the wall of the chamber defines areas where a plasma might damage or create cleaning problems. The cusp pattern is shifted to improve operation of the substrate processing system and to reduce the damage and/or cleaning problems caused by the plasma's interaction with the wall. Shifting of the cusp pattern can be accomplished by either moving the magnetic array or by moving the chamber wall.

Abstract: A plasma processing system for processing a substrate which includes a single chamber, substantially azimuthally symmetric plasma processing chamber within which a plasma is both ignited and sustained for the processing. The plasma processing chamber has no separate plasma generation chamber. The plasma processing chamber has an upper end and a lower end. The plasma processing system includes a coupling window disposed at an upper end of the plasma processing chamber and an RF antenna arrangement disposed above a plane defined by the substrate when the substrate is disposed within the plasma processing chamber for the processing. The plasma processing system also includes an electromagnet arrangement disposed above the plane defined by the substrate.

Abstract: A low pressure process is described for the anisotropic etching of a titanium or tantalum silicide layer formed over a polysilicon layer on a gate oxide layer, and then masked. The etch process is carried out at a low pressure of about 10 milliTorr to about 30 milliTorr using Cl.sub.2 and HBr etching gases, preferably only Cl.sub.2 at the etching gas, to etch the silicide without undercutting the mask layer. In a preferred embodiment, etch residues are also eliminated by the use of only Cl.sub.2 as the etching gas in the low pressure etch step. In the most prefferred embodiment, any bulges which might otherwise remain in the sidewalls of the underlying polysilicon layer, are also eliminated by using only HBr as the etching gas in the over-etch step, which is highly selective to oxide to protect the underlying gate oxide layer; resulting in an anisotropic etch of both the titanium/tantalum silicide and polysilicon layers, without leaving etch residues on the wafer surface.