Abstract: Embodiments of methods for fabricating a silicon nitride stack on a semiconductor substrate are provided herein. In one embodiment, a method for fabricating a silicon nitride stack on a semiconductor substrate includes depositing a base layer including silicon nitride on the substrate using a first set of process conditions that selectively control the stress of the base layer; and depositing an upper layer including silicon nitride using a second set of process conditions that selectively control at least one of an oxidation resistance and a refractive index of the upper layer.

Abstract: A method and apparatus for depositing silicon boron nitride films is provided. The apparatus comprises a chamber, a gas mixing block connected to the chamber, and separate boron-containing precursor, silicon-containing precursor, and nitrogen-containing precursor gas line systems that are connected to the gas mixing block. Methods of depositing a silicon boron nitride film in the apparatus are provided. In another aspect, a method of depositing a silicon boron nitride film includes reacting a boron-containing precursor, silicon-containing precursor, and nitrogen-containing precursor in a chamber, wherein a ratio of the flow rate of the nitrogen-containing precursor into the chamber to the flow rate of the boron-containing precursor is greater than or equal to about 10.

Abstract: A CMOS gate stack that increases the inversion capacitance compared to a conventional CMOS gate stack has been described. Using a poly-SiGe gate, instead of the conventional poly-Si gate near the gate dielectric layer, increases the amount of implanted dopant that can be activated. This increase overcomes the polysilicon depletion problem that limits the inversion capacitance in the conventional CMOS gate stack. To integrate the poly-SiGe layer into the gate stack, a thin ?-Si layer is deposited between the gate dielectric layer and the poly-SiGe layer. To ensure proper salicide formation, a poly-Si layer is capped over the poly-SiGe layer. In order to obtain a fined-grained poly-Si over poly-SiGe, a second ?-Si layer is deposited between the poly-Si layer and the poly-SiGe layer.

Abstract: Embodiments of methods for fabricating a silicon nitride stack on a semiconductor substrate are provided herein. In one embodiment, a method for fabricating a silicon nitride stack on a semiconductor substrate includes depositing a base layer comprising silicon nitride on the substrate using a first set of process conditions that selectively control the stress of the base layer; and depositing an upper layer comprising silicon nitride using a second set of process conditions that selectively control at least one of an oxidation resistance and a refractive index of the upper layer.

Abstract: A method and apparatus for low temperature deposition of doped silicon nitride films is disclosed. The improvements include a mechanical design for a CVD chamber that provides uniform heat distribution for low temperature processing and uniform distribution of process chemicals, and methods for depositing at least one layer comprising silicon and nitrogen on a substrate by heating a substrate, flowing a silicon containing precursor into a processing chamber having a mixing region defined by an adaptor ring and one or more blocker plates and an exhaust system heating the adapter ring and a portion of the exhaust system, flowing one or more of a hydrogen, germanium, boron, or carbon containing precursor into the processing chamber, and optionally flowing a nitrogen containing precursor into the processing chamber.

Abstract: A CMOS gate stack that increases the inversion capacitance compared to a conventional CMOS gate stack has been described. Using a poly-SiGe gate, instead of the conventional poly-Si gate near the gate dielectric layer, increases the amount of implanted dopant that can be activated. This increase overcomes the polysilicon depletion problem that limits the inversion capacitance in the conventional CMOS gate stack. To integrate the poly-SiGe layer into the gate stack, a thin ?-Si layer is deposited between the gate dielectric layer and the poly-SiGe layer. To ensure proper salicide formation, a poly-Si layer is capped over the poly-SiGe layer. In order to obtain a fined-grained poly-Si over poly-SiGe, a second ?-Si layer is deposited between the poly-Si layer and the poly-SiGe layer.

Abstract: A silicon nitride layer is deposited on a substrate within a processing region by introducing a silicon containing precursor into the processing region, exhausting gases in the processing region including the silicon containing precursor while uniformly, gradually reducing a pressure of the processing region, introducing a nitrogen containing precursor into the processing region, and exhausting gases in the processing region including the nitrogen containing precursor while uniformly, gradually reducing a pressure of the processing region. During the steps of exhausting, the slope of the pressure decrease with respect to time is substantially constant.

Abstract: A CMOS gate stack that increases the inversion capacitance compared to a conventional CMOS gate stack has been described. Using a poly-SiGe gate, instead of the conventional poly-Si gate near the gate dielectric layer, increases the amount of implanted dopant that can be activated. This increase overcomes the polysilicon depletion problem that limits the inversion capacitance in the conventional CMOS gate stack. To integrate the poly-SiGe layer into the gate stack, a thin ?-Si layer is deposited between the gate dielectric layer and the poly-SiGe layer. To ensure proper salicide formation, a poly-Si layer is capped over the poly-SiGe layer. In order to obtain a fined-grained poly-Si over poly-SiGe, a second ?-Si layer is deposited between the poly-Si layer and the poly-SiGe layer.