Patent application number | Description | Published |
20130020705 | METHOD TO FORM UNIFORM SILICIDE BY SELECTIVE IMPLANTATION - Methods form an integrated circuit structure by forming at least a portion of a plurality of devices within and/or on a substrate and patterning trenches in an inter-layer dielectric layer on the substrate adjacent the devices. The patterning forms relatively narrow trenches and relatively wide trenches. The methods then perform an angled implant of a compensating material into the trenches. The angle of the angled implant implants a greater concentration of the compensating material in the regions of the substrate at the bottom of the wider trenches relative to an amount of compensating material implanted in the regions of the substrate at the bottom of the narrower trenches. The methods then deposit a metallic material within the trenches and heat the metallic material to form silicide from the metallic material. | 01-24-2013 |
20130069124 | MOSFET INTEGRATED CIRCUIT WITH UNIFORMLY THIN SILICIDE LAYER AND METHODS FOR ITS MANUFACTURE - An MOSFET device having a Silicide layer of uniform thickness, and methods for its fabrication, are provided. One such method involves depositing a metal layer over wide and narrow contact trenches on the surface of a silicon semiconductor substrate. Upon formation of a uniformly thin amorphous intermixed alloy layer at the metal/silicon interface, the excess (unreacted) metal is removed. The device is annealed to facilitate the formation of a thin silicide layer on the substrate surface which exhibits uniform thickness at the bottoms of both wide and narrow contact trenches. | 03-21-2013 |
20130119483 | SILICIDE CONTACTS HAVING DIFFERENT SHAPES ON REGIONS OF A SEMICONDUCTOR DEVICE - A structure and method for fabricating silicide contacts for semiconductor devices is provided. Specifically, the structure and method involves utilizing chemical vapor deposition (CVD) and annealing to form silicide contacts of different shapes, selectively on regions of a semiconductor field effect transistor (FET), such as on source and drain regions. The shape of silicide contacts is a critical factor that can be manipulated to reduce contact resistance. Thus, the structure and method provide silicide contacts of different shapes with low contact resistance, wherein the silicide contacts also mitigate leakage current to enhance the utility and performance of FETs in low power applications. | 05-16-2013 |
20130137260 | MULTI-STAGE SILICIDATION PROCESS - A multi-stage silicidation process is described wherein a dielectric etch to expose contact regions is timed to be optimal for a highest of the contact regions. After exposing the highest of the contact regions, a silicide is formed on the exposed contact region and the dielectric is re-etched, selective to the formed silicide, to expose another contact region, lower than the highest of the contact regions, without recessing the highest of the contact regions. The process then forms a silicide on the lower contact region. The process may continue to varying depths. Each subsequent etch is performed without the use of additional masking steps. By manipulating diffusive properties of existing silicides and deposited metals, the silicides formed on contact regions with differing depths/height may comprise different compositions and be optimized for different polarity devices such as nFET and pFET devices. | 05-30-2013 |
20140154856 | Inducing Channel Strain via Encapsulated Silicide Formation - Methods of forming semiconductor structures having channel regions strained by encapsulated silicide formation. Embodiments include forming a transistor, depositing an interlevel dielectric (ILD) layer above the transistor, forming contact recesses exposing portions of source/drain regions of the transistor, forming metal-rich silicide layers on the exposed portions of the source/drain regions, forming metal contacts in the contact recesses above the metal-rich silicide layers, and converting the metal-rich silicide layer to a silicon-rich silicide layer. In other embodiments, the metal-rich silicide layers are formed on the source/drain regions prior to ILD layer deposition. Embodiments further include forming a transistor, depositing an ILD layer above the transistor, forming contact recesses exposing portions of source/drain regions of the transistor, forming metal liners in the contact recesses, forming metal fills in the contact recesses, and forming silicide layers on the source/drain regions by reacting portions of the metal liners with portions of the source/drain regions. | 06-05-2014 |
20150200291 | FIN END SPACER FOR PREVENTING MERGER OF RAISED ACTIVE REGIONS - After formation of gate structures over semiconductor fins and prior to formation of raised active regions, a directional ion beam is employed to form a dielectric material portion on end walls of semiconductor fins that are perpendicular to the lengthwise direction of the semiconductor fins. The angle of the directional ion beam is selected to be with a vertical plane including the lengthwise direction of the semiconductor fins, thereby avoiding formation of the dielectric material portion on lengthwise sidewalls of the semiconductor fins. Selective epitaxy of semiconductor material is performed to grow raised active regions from sidewall surfaces of the semiconductor fins. Optionally, horizontal portions of the dielectric material portion may be removed prior to the selective epitaxy process. Further, the dielectric material portion may optionally be removed after the selective epitaxy process. | 07-16-2015 |
20150270179 | DIFFUSION-CONTROLLED OXYGEN DEPLETION OF SEMICONDUCTOR CONTACT INTERFACE - A device is created by forming a layer of dielectric material on a silicon-containing region of a semiconductor substrate. An opening is created through the layer of dielectric material, the opening having a bottom and exposing the silicon-containing region. A metal stack is formed within the opening. The metal stack includes at least a first metal film on the silicon-containing region and a second gettering metal film on the first metal film. The metal stack is annealed to cause oxygen to migrate from the substrate to the gettering metal film. A first liner is formed within the opening. A fill metal is deposited in the opening. | 09-24-2015 |
20150270365 | SELECTIVE DIELECTRIC SPACER DEPOSITION FOR EXPOSING SIDEWALLS OF A FINFET - Angled directional ion beams are directed to sidewalls of a gate structure that straddles at least one semiconductor fin. The directions of the angled directional ion beams are contained within a vertical plane that is parallel to the sidewalls of the at least one semiconductor. A pair of gate spacers are formed on sidewalls of the gate structure by accumulation of the deposited dielectric material from the angled directional ion beams and without use of an anisotropic etch, while the sidewalls of the semiconductor fins parallel to the directional ion beams remain physically exposed. A selective epitaxy process can be performed to form raised active regions by growing a semiconductor material from the sidewalls of the semiconductor fins. | 09-24-2015 |