Abstract: The amount of Pt residues remaining after forming Pt-containing NiSi is reduced by performing an O2 flash while shaping gate spacers, and then cleaning and applying a second application of Aqua Regia. Embodiments include sputter depositing a layer of Ni/Pt on a semiconductor substrate, annealing the Ni/Pt layer, wet stripping unreacted Ni, annealing the Ni stripped Ni/Pt layer, stripping unreacted Pt from the annealed Ni/Pt layer, e.g., with Aqua Regia, treating the Pt stripped Ni/Pt layer with an oxygen plasma, cleaning the Ni/Pt layer, and stripping unreacted Pt from the cleaned Ni/Pt layer, e.g., with a second application of Aqua Regia.

Abstract: The amount of Pt residues remaining after forming Pt-containing NiSi is reduced by performing an O2 flash while shaping gate spacers, and then cleaning and applying a second application of Aqua Regia. Embodiments include sputter depositing a layer of Ni/Pt on a semiconductor substrate, annealing the Ni/Pt layer, wet stripping unreacted Ni, annealing the Ni stripped Ni/Pt layer, stripping unreacted Pt from the annealed Ni/Pt layer, e.g., with Aqua Regia, treating the Pt stripped Ni/Pt layer with an oxygen plasma, cleaning the Ni/Pt layer, and stripping unreacted Pt from the cleaned Ni/Pt layer, e.g., with a second application of Aqua Regia.

Abstract: When forming capacitive structures in a metallization system, such as in a dynamic RAM area, placeholder metal regions may be formed together with “regular” metal features, thereby achieving a very efficient overall process flow. At a certain manufacturing stage, the metal of the placeholder metal region may be removed on the basis of a wet chemical etch recipe followed by the deposition of the electrode materials and the dielectric materials for the capacitive structure without unduly affecting other portions of the metallization system. In this manner, very high capacitance values may be realized on the basis of a very efficient overall manufacturing flow.

Abstract: Three-dimensional transistors in a bulk configuration may be formed on the basis of gate openings or gate trenches provided in a mask material. Hence, self-aligned semiconductor fins may be efficiently patterned in the underlying active region in a portion defined by the gate opening, while other gate openings may be efficiently masked, in which planar transistors are to be provided. After patterning the semiconductor fins and adjusting the effective height thereof, the further processing may be continued on the basis of process techniques that may be commonly applied to the planar transistors and the three-dimensional transistors.

Abstract: Generally, the present disclosure is directed work function adjustment in high-k metal gate electrode structures. In one illustrative embodiment, a method is disclosed that includes removing a placeholder material of a first gate electrode structure and a second gate electrode structure, and forming a first work function adjusting material layer in the first and second gate electrode structures, wherein the first work function adjusting material layer includes a tantalum nitride layer. The method further includes removing a portion of the first work function adjusting material layer from the second gate electrode structure by using the tantalum nitride layer as an etch stop layer, removing the tantalum nitride layer by performing a wet chemical etch process, and forming a second work function adjusting material layer in the second gate electrode structure and above a non-removed portion of the first work function adjusting material layer in the first gate electrode structure.

Abstract: In a replacement gate approach, the sacrificial gate material is exposed on the basis of enhanced process uniformity, for instance during a wet chemical etch step or a CMP process, by forming a modified portion in the interlayer dielectric material by ion implantation. Consequently, the damaged portion may be removed with an increased removal rate while avoiding the creation of polymer contaminants when applying an etch process or avoiding over-polish time when applying a CMP process.

Abstract: In a replacement gate approach, the sacrificial gate material is exposed on the basis of enhanced process uniformity, for instance during a wet chemical etch step or a CMP process, by forming a modified portion in the interlayer dielectric material by ion implantation. Consequently, the damaged portion may be removed with an increased removal rate while avoiding the creation of polymer contaminants when applying an etch process or avoiding over-polish time when applying a CMP process.

Abstract: In a replacement gate approach in sophisticated semiconductor devices, a tantalum nitride etch stop material may be efficiently removed on the basis of a wet chemical etch recipe using ammonium hydroxide. Consequently, a further work function adjusting material may be formed with superior uniformity, while the efficiency of the subsequent adjusting of the work function may also be increased. Thus, superior uniformity, i.e., less pronounced transistor variability, may be accomplished on the basis of a replacement gate approach in which the work function of the gate electrodes of P-channel transistors and N-channel transistors is adjusted after completing the basic transistor configuration.

Abstract: The amount of Pt residues remaining after forming Pt-containing NiSi is reduced by performing an O2 flash while shaping gate spacers, and then cleaning and applying a second application of Aqua Regia. Embodiments include sputter depositing a layer of Ni/Pt on a semiconductor substrate, annealing the Ni/Pt layer, wet stripping unreacted Ni, annealing the Ni stripped Ni/Pt layer, stripping unreacted Pt from the annealed Ni/Pt layer, e.g., with Aqua Regia, treating the Pt stripped Ni/Pt layer with an oxygen plasma, cleaning the Ni/Pt layer, and stripping unreacted Pt from the cleaned Ni/Pt layer, e.g., with a second application of Aqua Regia.

Abstract: When forming capacitive structures in a metallization system, such as in a dynamic RAM area, placeholder metal regions may be formed together with “regular” metal features, thereby achieving a very efficient overall process flow. At a certain manufacturing stage, the metal of the placeholder metal region may be removed on the basis of a wet chemical etch recipe followed by the deposition of the electrode materials and the dielectric materials for the capacitive structure without unduly affecting other portions of the metallization system. In this manner, very high capacitance values may be realized on the basis of a very efficient overall manufacturing flow.

Abstract: In a replacement gate approach, the sacrificial gate material is exposed on the basis of enhanced process uniformity, for instance during a wet chemical etch step or a CMP process, by forming a modified portion in the interlayer dielectric material by ion implantation. Consequently, the damaged portion may be removed with an increased removal rate while avoiding the creation of polymer contaminants when applying an etch process or avoiding over-polish time when applying a CMP process.

Abstract: Three-dimensional transistors in a bulk configuration may be formed on the basis of gate openings or gate trenches provided in a mask material. Hence, self-aligned semiconductor fins may be efficiently patterned in the underlying active region in a portion defined by the gate opening, while other gate openings may be efficiently masked, in which planar transistors are to be provided. After patterning the semiconductor fins and adjusting the effective height thereof, the further processing may be continued on the basis of process techniques that may be commonly applied to the planar transistors and the three-dimensional transistors.

Abstract: In a replacement gate approach, the sacrificial gate material is exposed on the basis of enhanced process uniformity, for instance during a wet chemical etch step or a CMP process, by forming a modified portion in the interlayer dielectric material by ion implantation. Consequently, the damaged portion may be removed with an increased removal rate while avoiding the creation of polymer contaminants when applying an etch process or avoiding over-polish time when applying a CMP process.

Abstract: In a replacement gate approach in sophisticated semiconductor devices, a tantalum nitride etch stop material may be efficiently removed on the basis of a wet chemical etch recipe using ammonium hydroxide. Consequently, a further work function adjusting material may be formed with superior uniformity, while the efficiency of the subsequent adjusting of the work function may also be increased. Thus, superior uniformity, i.e., less pronounced transistor variability, may be accomplished on the basis of a replacement gate approach in which the work function of the gate electrodes of P-channel transistors and N-channel transistors is adjusted after completing the basic transistor configuration.