Abstract: An advanced gate structure that includes a fully silicided metal gate and silicided source and drain regions in which the fully silicided metal gate has a thickness that is greater than the thickness of the silicided source/drain regions is provided. A method of forming the advanced gate structure is also provided in which the silicided source and drain regions are formed prior to formation of the silicided metal gate region.

Abstract: A method of forming a salicide on a semiconductor device includes depositing a first refractory metal layer over a silicon region of a substrate, depositing a near-noble metal layer over the first refractory metal layer, and depositing a second refractory metal layer over the near-noble metal layer. The semiconductor device is annealed in a first annealing process to form a silicide layer abutting the doped region of the semiconductor device. Un-reacted portions of the near-noble metal layer and the second refractory metal layer are removed. The device may be annealed in an optional second annealing process to convert the silicide layer to a low resistance phase silicide material. Junction leakage and bridging are minimized or eliminated by embodiments of the present invention, and a smoother silicided surface is achieved.

Abstract: A method for cleaning a semiconductor interconnect structure formed in an organic ILD using an anisotropic organic dielectric etch in combination with a sputter clean process. Organic material displaced from the sidewalls to the bottom of the structure by the sputter clean is removed by the ion enhanced organic etch. Interconnect resistance shift is reduced and reliability of the interconnect structure is improved by removing contaminates at the interface of the via/contact, and by increasing adhesion of the liner or plug to the underlying conductive layer.

Abstract: A method of forming organic spacers using an N2 plasma or N2 containing plasma anisotropic etchant, and using such organic spacers for forming features on a semiconductor structure such as vias having a smaller dimension than can be defined by lithographic techniques Other features formed according to the teachings of this invention include Source/Drain (S/D) areas, LDD/extension areas and graded junctions with larger S/D silicide/contact areas. The process for forming the organic spacers comprises conformally coating a patterned semiconductor structure with an organic material such as, for example, an antireflective coating. The coated structure is then anisotropically etched with N2 plasma or N2 containing plasma which forms the organic spacers.

Abstract: A method of forming organic spacers using an N2 plasma or N2 containing plasma anisotropic etchant, and using such organic spacers for forming features on a semiconductor structure such as vias having a smaller dimension than can be defined by lithographic techniques Other features formed according to the teachings of this invention include Source/Drain (S/D) areas, LDD/extension areas and graded junctions with larger S/D silicide/contact areas. The process for forming the organic spacers comprises conformally coating a patterned semiconductor structure with an organic material such as, for example, an antireflective coating. The coated structure is then anisotropically etched with N2 plasma or N2 containing plasma which forms the organic spacers.

Abstract: A method of forming a salicide on a semiconductor device includes depositing a first refractory metal layer over a silicon region of a substrate, depositing a near-noble metal layer over the first refractory metal layer, and depositing a second refractory metal layer over the near-noble metal layer. The semiconductor device is annealed in a first annealing process to form a silicide layer abutting the doped region of the semiconductor device. Un-reacted portions of the near-noble metal layer and the second refractory metal layer are removed. The device may be annealed in an optional second annealing process to convert the silicide layer to a low resistance phase silicide material. Junction leakage and bridging are minimized or eliminated by embodiments of the present invention, and a smoother silicided surface is achieved.

Abstract: A method of fabricating a semiconductor device having a dielectric structure on which an interconnect structure is optionally patterned using lithographic and etching techniques, within a single deposition chamber, is provided. The dielectric structure may optionally be covered by diffusion barrier materials prior to a sputter etching process. This sputter etching process is used to remove the native oxide on an underneath metal conductor surface and includes a directional gaseous bombardment with simultaneous deposition of metal neutral. Diffusion barrier materials may also be deposited into the pattern.

Abstract: A method of forming organic spacers using an N2 plasma or N2 containing plasma anisotropic etchant, and using such organic spacers for forming features on a semiconductor structure such as vias having a smaller dimension than can be defined by lithographic techniques Other features formed according to the teachings of this invention include Source/Drain (S/D) areas, LDD/extension areas and graded junctions with larger S/D silicide/contact areas. The process for forming the organic spacers comprises conformally coating a patterned semiconductor structure with an organic material such as, for example, an antireflective coating. The coated structure is then anisotropically etched with N2 plasma or N2 containing plasma which forms the organic spacers.

Abstract: A method for cleaning a semiconductor interconnect structure formed in an organic ILD using an anisotropic organic dielectric etch in combination with a sputter clean process. Organic material displaced from the sidewalls to the bottom of the structure by the sputter clean is removed by the ion enhanced organic etch. Interconnect resistance shift is reduced and reliability of the interconnect structure is improved by removing contaminates at the interface of the via/contact, and by increasing adhesion of the liner or plug to the underlying conductive layer.