Patent application number | Description | Published |
20140361351 | GATE ELECTRODE WITH STABILIZED METAL SEMICONDUCTOR ALLOY-SEMICONDUCTOR STACK - A gate structure is provided on a channel portion of a semiconductor substrate. The gate structure may include an electrically conducting layer present on a gate dielectric layer, a semiconductor-containing layer present on the electrically conducting layer, a metal semiconductor alloy layer present on the semiconductor-containing layer, and a dielectric capping layer overlaying the metal semiconductor alloy layer. In some embodiments, carbon and/or nitrogen can be present within the semiconductor-containing layer, the metal semiconductor alloy layer or both the semiconductor-containing layer and the metal semiconductor alloy layer. The presence of carbon and/or nitrogen within the semiconductor-containing layer and/or the metal semiconductor alloy layer provides stability to the gate structure. In another embodiment, a layer of carbon and/or nitrogen can be formed between the semiconductor-containing layer and the metal semiconductor alloy layer. | 12-11-2014 |
20140363964 | GATE ELECTRODE WITH STABILIZED METAL SEMICONDUCTOR ALLOY-SEMICONDUCTOR STACK - A gate structure is provided on a channel portion of a semiconductor substrate. The gate structure may include an electrically conducting layer present on a gate dielectric layer, a semiconductor-containing layer present on the electrically conducting layer, a metal semiconductor alloy layer present on the semiconductor-containing layer, and a dielectric capping layer overlaying the metal semiconductor alloy layer. In some embodiments, carbon and/or nitrogen can be present within the semiconductor-containing layer, the metal semiconductor alloy layer or both the semiconductor-containing layer and the metal semiconductor alloy layer. The presence of carbon and/or nitrogen within the semiconductor-containing layer and/or the metal semiconductor alloy layer provides stability to the gate structure. In another embodiment, a layer of carbon and/or nitrogen can be formed between the semiconductor-containing layer and the metal semiconductor alloy layer. | 12-11-2014 |
20150221740 | METAL SEMICONDUCTOR ALLOY CONTACT RESISTANCE IMPROVEMENT - Contact openings are formed into a dielectric material exposing a surface portion of a semiconductor substrate. A first transition metal liner including at least one first transition metal element, a second transition metal liner including at least one second transition metal element that is different from the at least one first transition metal element and a metal contact are sequentially formed within each contact opening. Following a planarization process, the structure is annealed forming metal semiconductor alloy contacts at the bottom of each contact opening. Each metal semiconductor alloy contact that is formed includes the at least one first transition metal element, the at least one second transition metal element and a semiconductor element. | 08-06-2015 |
20150227137 | OPTIMIZATION OF A LASER ANNEAL BEAM PATH FOR MAXIMIZING CHIP YIELD - Semiconductor chips with curable out of specification measured values of an anneal-activated parameter are identified at a test step. A plurality of anneal plans are generated to include at least one of the identified semiconductor chips. A net yield improvement is calculated for each anneal plan. Each anneal plan includes the paths of a laser beam across the wafer to be irradiated, and optionally includes an azimuthal angle of the wafer as a function of time. The net yield improvement is the difference between an estimated yield improvement from selected target semiconductor chips for irradiation and an estimated yield loss due to collateral irradiation of functional semiconductor chips for each anneal plan. After simulating the net yield improvements for all the anneal plans, the anneal plan providing the greatest net yield improvement can be selected and utilized. | 08-13-2015 |
20150270168 | SEMICONDUCTOR CONTACT WITH DIFFUSION-CONTROLLED IN SITU INSULATOR FORMATION - A contact 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. An oxygen-containing layer is formed on type of the semiconductor substrate. A metal stack is formed within the opening and includes a first metal film with a first type of metal and a second type of metal and a second metal film. The metal stack, the oxygen-containing layer and the silicon-containing region of the semiconductor substrate are annealed to form a metallic oxide layer and a metal silicide layer. A first liner is formed within the opening. A fill metal is deposited in the opening. | 09-24-2015 |
20150270178 | DIFFUSION-CONTROLLED SEMICONDUCTOR CONTACT CREATION - A contact can be formed 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 that exposes the silicon-containing region. A metal stack is formed within the opening. The metal stack includes at least a first metal film having a first and second type of metal and a second metal film. The metal stack and the silicon-containing region of the semiconductor substrate are annealed to form a silicide that includes the first and second types of metal and that is in contact with the semiconductor substrate. A first liner is formed within the opening and a fill metal is deposited in the opening. | 09-24-2015 |
20150270222 | OXIDE MEDIATED EPITAXIAL NICKEL DISILICIDE ALLOY CONTACT FORMATION - Contact openings are formed into a dielectric material exposing a surface portion of a semiconductor substrate. An interfacial oxide layer is then formed in each contact opening and on an exposed surface portion of the interfacial oxide layer. A NiPt alloy layer is formed within each opening and on the exposed surface portion of each interfacial oxide layer. An anneal is then performed that forms a contact structure of, from bottom to top, a nickel disilicide alloy body having an inverted pyramidal shape, a Pt rich silicide cap region and an oxygen rich region. A metal contact is then formed within each contact opening and atop the oxygen rich region of each contact structure. | 09-24-2015 |
20150279925 | DT CAPACITOR WITH SILICIDE OUTER ELECTRODE AND/OR COMPRESSIVE STRESS LAYER, AND RELATED METHODS - Method of forming a deep trench capacitor are provided. The method may include forming a deep trench in a substrate; enlarging a width of a lower portion of the deep trench to be wider than a width of the rest of the deep trench; epitaxially forming a compressive stress layer in the lower portion of the deep trench; forming a metal-insulator-metal (MIM) stack within the lower portion of the deep trench; and filling a remaining portion of the deep trench with a semiconductor. Alternatively to forming the compressive stress layer or in addition thereto, a silicide may be formed by co-deposition of a refractory metal and silicon. | 10-01-2015 |