Abstract: In the preferred embodiment, a gate dielectric and an electrode are formed on a substrate. A pair of spacers is formed along opposite sidewalls of the gate electrode and the gate dielectric. Spacers are preferably formed of SiCO based material or SiCN based material. The source and drain are then formed. A contact etch stop (CES) layer is formed on the source/drain regions and the spacers. The CES layer is preferably formed of SiCO based material or SiCN based material. An Inter-Level Dielectric (ILD) is then formed on the CES layer.

Abstract: A new method is provided for the creation of CMOS devices. A sacrificial layer is deposited over a silicon substrate. This sacrificial layer is instrumental in creating gate spacers and in doing so serves to separate the gate from the source/drain regions in a self-aligned manner.

Abstract: A method of fabricating a strained-silicon structure comprising the following steps. A substrate having an insulator layer formed thereover is provided. A silicon-on-insulator layer is formed over the insulator layer. A first SiGe layer is formed over the silicon-on-insulator layer. The first SiGe layer being strained. At least the first SiGe layer is annealed to convert the strained SiGe layer to a relaxed first SiGe layer. A second SiGe layer, having the same composition as the first SiGe layer, is formed over the first SiGe layer. The second SiGe layer being relaxed. An epitaxial silicon layer is grown over the second SiGe layer. The epitaxial silicon layer being strained to complete formation of the strained-silicon structure.

Abstract: A method of simultaneously forming a high-k metal oxide dielectric layer and a gate oxide dielectric layer comprising the following steps. A structure having isolation regions which separate the structure into at least one core device active region and one I/O active region is provided. A buffer layer is formed over the structure and the isolation regions. A metal containing layer is formed over the buffer layer. The metal containing layer and the buffer layer are patterned to: form an exposed patterned metal containing layer within the at least one core device action region; and expose the structure within the at least one I/O active region. The exposed patterned metal containing layer and the exposed structure within the at least one I/O active region are oxidized to simultaneously form: the high-k metal oxide dielectric layer within the at least one core device active region; and the gate oxide dielectric layer within the at least one I/O active region.

Abstract: A method to reduce via poisoning in low-k copper dual damascene interconnects through ultraviolet (UV) irradiation of the damascene structure is disclosed. This is accomplished by irradiating the insulative layers each time the layers are etched to form a portion of the damascene structure. Thus, irradiation is performed once after the forming of a trench or a via, and again for the second time when the insulative layers are etched to form the remaining trench or via. The trench and hole openings of the dual damascene structure are exposed to UV light in a dry ozone environment, which then favorably alters the surface characteristics of the low-k dielectric walls which are normally hydrophobic. Hence, during etching, moisture is not absorbed into the walls.

Abstract: Current aqueous methods for removal of polymeric materials from the sidewalls of trenches etched into silicon wafers by reactive-ion-etching are inadequate for treating deep trenches having high aspect ratios. Spin-dry operations performed after the aqueous etching are incapable of completely removing rinse water and ionic species from these deep trenches, thereby leaving pockets of liquid. Subsequent evaporation of these pockets results in the concentration and eventual precipitation of residual ionic species creating watermarks. A two stage cleaning method is described in which the first stage dissolves the sidewall polymer and the second stage draws ionic species strongly chemisorbed onto the silicon surfaces into solution. A key feature of the method is that the wafer surface is not permitted to dry until after the final rinse.

Abstract: A field oxide region and method of forming a field oxide region using a LOCOS process and nitride spacers formed on the sidewalls of the field oxide regions. During the LOCOS process recesses are formed in the field oxide which result in poor step coverage during successive process steps. Nitride spacers are formed on the sidewalls of the field oxide covering the recesses. The spacers provide a smooth surface over the field oxide and improved step coverage during subsequent process steps.