Patent application number | Description | Published |
20110316046 | Field Effect Transistor Device - A method for forming a field effect transistor device includes forming a gate stack portion on a substrate, forming a spacer portion on the gates stack portion and a portion of the substrate, removing an exposed portion of the substrate, epitaxially growing a first silicon material on the exposed portion of the substrate, removing a portion of the epitaxially grown first silicon material to expose a second portion of the substrate, and epitaxially growing a second silicon material on the exposed second portion of the substrate and the first silicon material. | 12-29-2011 |
20120112208 | STRESSED TRANSISTOR WITH IMPROVED METASTABILITY - An embedded, strained epitaxial semiconductor material, i.e., an embedded stressor element, is formed at the footprint of at least one pre-fabricated field effect transistor that includes at least a patterned gate stack, a source region and a drain region. As a result, the metastability of the embedded, strained epitaxial semiconductor material is preserved and implant and anneal based relaxation mechanisms are avoided since the implants and anneals are performed prior to forming the embedded, strained epitaxial semiconductor material. | 05-10-2012 |
20130134444 | STRESSED TRANSISTOR WITH IMPROVED METASTABILITY - An embedded, strained epitaxial semiconductor material, i.e., an embedded stressor element, is formed at the footprint of at least one pre-fabricated field effect transistor that includes at least a patterned gate stack, a source region and a drain region. As a result, the metastability of the embedded, strained epitaxial semiconductor material is preserved and implant and anneal based relaxation mechanisms are avoided since the implants and anneals are performed prior to forming the embedded, strained epitaxial semiconductor material. | 05-30-2013 |
20130175547 | FIELD EFFECT TRANSISTOR DEVICE - A method for forming a field effect transistor device includes forming a gate stack portion on a substrate, forming a spacer portion on the gates stack portion and a portion of the substrate, removing an exposed portion of the substrate, epitaxially growing a first silicon material on the exposed portion of the substrate, removing a portion of the epitaxially grown first silicon material to expose a second portion of the substrate, and epitaxially growing a second silicon material on the exposed second portion of the substrate and the first silicon material. | 07-11-2013 |
20140264558 | FACETED INTRINSIC EPITAXIAL BUFFER LAYER FOR REDUCING SHORT CHANNEL EFFECTS WHILE MAXIMIZING CHANNEL STRESS LEVELS - A faceted intrinsic buffer semiconductor material is deposited on sidewalls of a source trench and a drain trench by selective epitaxy. A facet adjoins each edge at which an outer sidewall of a gate spacer adjoins a sidewall of the source trench or the drain trench. A doped semiconductor material is subsequently deposited to fill the source trench and the drain trench. The doped semiconductor material can be deposited such that the facets of the intrinsic buffer semiconductor material are extended and inner sidewalls of the deposited doped semiconductor material merges in each of the source trench and the drain trench. The doped semiconductor material can subsequently grow upward. Faceted intrinsic buffer semiconductor material portions allow greater outdiffusion of dopants near faceted corners while suppressing diffusion of dopants in regions of uniform width, thereby suppressing short channel effects. | 09-18-2014 |
20150084096 | FACETED INTRINSIC EPITAXIAL BUFFER LAYER FOR REDUCING SHORT CHANNEL EFFECTS WHILE MAXIMIZING CHANNEL STRESS LEVELS - A faceted intrinsic buffer semiconductor material is deposited on sidewalls of a source trench and a drain trench by selective epitaxy. A facet adjoins each edge at which an outer sidewall of a gate spacer adjoins a sidewall of the source trench or the drain trench. A doped semiconductor material is subsequently deposited to fill the source trench and the drain trench. The doped semiconductor material can be deposited such that the facets of the intrinsic buffer semiconductor material are extended and inner sidewalls of the deposited doped semiconductor material merges in each of the source trench and the drain trench. The doped semiconductor material can subsequently grow upward. Faceted intrinsic buffer semiconductor material portions allow greater outdiffusion of dopants near faceted corners while suppressing diffusion of dopants in regions of uniform width, thereby suppressing short channel effects. | 03-26-2015 |
20150097270 | FINFET WITH RELAXED SILICON-GERMANIUM FINS - A method of forming a semiconductor structure includes forming a first fin in a p-FET device region of a semiconductor substrate and a second fin in an n-FET device region of the semiconductor substrate substantially parallel to the first fin. The first fin and the second fin each comprise a strained semiconductor material. Next, the second fin is amorphized to form a relaxed fin by implanting ions into the second fin while protecting the first fin. | 04-09-2015 |
20150206876 | FIN FIELD EFFECT TRANSISTORS HAVING HETEROEPITAXIAL CHANNELS - Disposable gate structures are formed over semiconductor material portions, and source and drain regions can be formed in the semiconductor material portions. After formation of a planarization dielectric layer, one type of disposable gate structure can be removed selective to at least another type of disposable gate structure employing a patterned hard dielectric mask layer. After recessing a surface portion of a body portion, a heteroepitaxial channel portion is formed on the remaining physically exposed portion of the body portion by selective epitaxy of a semiconductor material different from the semiconductor material of the remaining body portion. A plurality of types of heteroepitaxial channel portions can be formed in different types of semiconductor devices. Replacement gate structures can be formed in the gate cavities to provide field effect transistors having different threshold voltages. | 07-23-2015 |