Abstract: A method of depositing titanium nitride by chemical vapor deposition in a chamber having several design features directed to the conductive nature of titanium nitride, particularly when a plasma treatment step is performed after the thermal deposition of the film. Preferably, during the post-deposition plasma treatment, RF power is applied only to the showerhead counter-electrode and none to the pedestal supporting the wafer, thereby preventing charging of the wafer.

Abstract: The construction of a film on a wafer, which is placed in a processing chamber, may be carried out through the following steps. A layer of material is deposited on the wafer. Next, the layer of material is annealed. Once the annealing is completed, the material may be oxidized. Alternatively, the material may be exposed to a silicon gas once the annealing is completed. The deposition, annealing, and either oxidation or silicon gas exposure may all be carried out in the same chamber, without need for removing the wafer from the chamber until all three steps are completed. A semiconductor wafer processing chamber for carrying out such an in-situ construction may include a processing chamber, a showerhead, a wafer support and a rf signal means. The showerhead supplies gases into the processing chamber, while the wafer support supports a wafer in the processing chamber.

Abstract: A method of depositing titanium nitride by chemical vapor deposition in a chamber having several design features directed to the conductive nature of titanium nitride, particularly when a plasma treatment step is performed after the thermal deposition of the film. Preferably, during the post-deposition plasma treatment, RF power is applied only to the showerhead counter-electrode and none to the pedestal supporting the wafer, thereby preventing charging of the wafer.

Abstract: The present invention provides an approach which provides an increase in the number of usable substrates with a film, such as titanium nitride, deposited thereon at a sufficient deposition rate and where the film meets uniformity and resistivity specifications as well as providing good step coverage. In accordance with an embodiment, the present invention provides an apparatus for substrate processing. The apparatus circulates a heat exchange medium through a passage in a chamber body of a vacuum chamber, and heats a heater pedestal having a surface for supporting the substrate to a heater temperature. The heat exchange medium has a heat exchange temperature of about 60.degree. C. or less. The the apparatus also flows a gas into the chamber at a flow rate to deposit a film on a substrate, where the flow rate provides an effective temperature of the substrate lower than the heater temperature and where the film meets uniformity and resistance specifications after deposition onto a number of substrates.

Abstract: A substrate processing chamber, particularly a chemical vapor deposition (CVD) chamber used both for thermal deposition of a conductive material and a subsequently performed plasma process. The invention reduces thermal deposition of the conductive material in a pumping channel exhausting the chamber. The pumping channel is lined with various elements, some of which are electrically floating and which are designed so that conductive material deposited on these elements do not deleteriously affect a plasma generated for processing the wafer.

Abstract: Multilayer diffusion barriers are used in integrated circuits. These diffusion barriers provide high electrical conductivity to carry current efficiently with fast response time, and additionally suppress diffusion between interconnect conductors, e.g. Cu, and the semiconductor device. Moreover, the present multilayer diffusion barriers adhere well to the underlying materials as well as to Cu.In a preferred embodiment, the diffusion barriers comprise bilayers, each containing a first sublayer formed of a refractory metal, or a refractory metal nitride; and a second sublayer formed of a refractory metal nitride, a refractory metal silicon nitride, a refractory metal silicon boride, or a refractory metal oxonitride.Multilayer diffusion barriers are deposited easily by CVD in a multistation module. The present structures can be applied to sub-0.25 .mu.m logic, memory and application specific circuits with Cu as the primary conductor.

Abstract: A substrate processing chamber, particularly a chemical vapor deposition (CVD) chamber used both for thermal deposition of a conductive material and a subsequently performed plasma process. The invention reduces thermal deposition of the conductive material on peripheral portions of the pedestal supporting a wafer and in a pumping channel exhausting the chamber. A peripheral ring placed on the pedestal, preferably also used to center the wafer, is thermally isolated from the pedestal so that its temperature is kept substantially lower than that of the wafer. Despite its thermal isolation, the peripheral ring is electrically connected to the pedestal to prevent arcing. The pumping channel is lined with various elements, some of which are electrically floating and which are designed so that conductive material deposited on these elements do not deleteriously affect a plasma generated for processing the wafer.