Abstract: Systems and methods are provided for contact formation. A semiconductor structure is provided. The semiconductor structure includes an opening formed by a bottom surface and one or more side surfaces. A first conductive material is formed on the bottom surface and the one or more side surfaces to partially fill the opening, the first conductive material including a top portion and a bottom portion. Ion implantation is formed on the first conductive material, the top portion of the first conductive material being associated with a first ion density, the bottom portion of the first conductive material being associated with a second ion density lower than the first ion density. At least part of the top portion of the first conductive material is removed. A second conductive material is formed to fill the opening.

Abstract: A semiconductor device and methods of formation are provided. A semiconductor device includes an annealed cobalt plug over a silicide in a first opening of the semiconductor device, wherein the annealed cobalt plug has a repaired lattice structure. The annealed cobalt plug is formed by annealing a cobalt plug at a first temperature for a first duration, while exposing the cobalt plug to a first gas. The repaired lattice structure of the annealed cobalt plug is more regular or homogenized as compared to a cobalt plug that is not so annealed, such that the annealed cobalt plug has a relatively increased conductivity or reduced resistivity.

Abstract: A method includes forming a gate stack over a semiconductor region, depositing an impurity layer over the semiconductor region, and depositing a metal layer over the impurity layer. An annealing is then performed, wherein the elements in the impurity layer are diffused into a portion of the semiconductor region by the annealing to form a source/drain region, and wherein the metal layer reacts with a surface layer of the portion of the semiconductor region to form a source/drain silicide region over the source/drain region.

Abstract: Systems and methods are provided for reducing a contact resistivity associated with a semiconductor device structure. A substrate including a semiconductor region is provided. One or more dielectric layers are formed on the semiconductor region, the one or more dielectric layers including an element. A gaseous material is applied on the one or more dielectric layers to change a concentration of the element in the one or more dielectric layers. A contact layer is formed on the one or more dielectric layers to generate a semiconductor device structure. The semiconductor device structure includes the contact layer, the one or more dielectric layers, and the semiconductor region. A contact resistivity associated with the semiconductor device structure is reduced by changing the concentration of the element in the one or more dielectric layers.

Abstract: Systems and methods are provided for reducing a contact resistivity associated with a semiconductor device structure. A substrate including a semiconductor region is provided. One or more dielectric layers are formed on the semiconductor region, the one or more dielectric layers including an element. A gaseous material is applied on the one or more dielectric layers to change a concentration of the element in the one or more dielectric layers. A contact layer is formed on the one or more dielectric layers to generate a semiconductor device structure. The semiconductor device structure includes the contact layer, the one or more dielectric layers, and the semiconductor region. A contact resistivity associated with the semiconductor device structure is reduced by changing the concentration of the element in the one or more dielectric layers.