| Patent application number | Description | Published |
|---|
| 20090035902 | INTEGRATED METHOD OF FABRICATING A MEMORY DEVICE WITH REDUCED PITCH - Provided is a method of fabricating a memory device. A substrate including an array region and a peripheral region is provided. A first feature and a second feature are formed in the array region. The first feature and the second feature have a first pitch. A plurality of spacers abutting each of the first feature and the second feature are formed. The plurality of spacers have a second pitch. A third feature in the peripheral region and a fourth and fifth feature in the array region are formed concurrently. The forth and fifth feature have the second pitch. | 02-05-2009 |
| 20090203217 | NOVEL SELF-ALIGNED ETCH METHOD FOR PATTERNING SMALL CRITICAL DIMENSIONS - A method is disclosed for etching an integrated circuit structure within a trench. A layer to be etched is applied over the structure and within the trench. A CF-based polymer is deposited over the layer to be etched followed by deposition of a capping layer of SiOCl-based polymer. The CF-based polymer reduces the width of the trench to such an extent that little or no SiOCl-based polymer is deposited at the bottom of the trench. An O | 08-13-2009 |
| 20100006974 | STORAGE NITRIDE ENCAPSULATION FOR NON-PLANAR SONOS NAND FLASH CHARGE RETENTION - The present disclosure provides a method of manufacturing a microelectronic device. The method includes forming recessed shallow trench isolation (STI) features in a semiconductor substrate, defining a semiconductor region between adjacent two of the recessed STI features; forming a tunnel dielectric feature within the semiconductor region; forming a nitride layer on the recessed STI features and the tunnel dielectric feature; etching the nitride layer to form nitride openings within the recessed STI features; partially removing the recessed STI features through the nitride openings, resulting in gaps between the nitride layer and the recessed STI features; and forming a first dielectric material on surfaces of the nitride layer, sealing the nitride openings. | 01-14-2010 |
| 20100072553 | METAL GATE STRESS FILM FOR MOBILITY ENHANCEMENT IN FinFET DEVICE - A CMOS FinFET semiconductor device provides an NMOS FinFET device that includes a compressive stress metal gate layer over semiconductor fins and a PMOS FinFET device that includes a tensile stress metal gate layer over semiconductor fins. A process for forming the same includes a selective annealing process that selectively converts a compressive metal gate film formed over the PMOS device to the tensile stress metal gate film. | 03-25-2010 |
| 20100183961 | INTEGRATED CIRCUIT LAYOUT DESIGN - Provided is a method including layout design of an integrated circuit. A first pattern is provided. The first pattern includes an array of dummy line features and a plurality of spacer elements abutting the dummy line features. A second pattern is provided. The second pattern defines an active region of an integrated circuit device. An edge spacer element of the active region is determined. A dummy line feature of the array of dummy line features is biased (e.g., increased in width), the dummy line feature is adjacent an edge spacer element. | 07-22-2010 |
| 20100203734 | METHOD OF PITCH HALVING - The present disclosure provides a method of fabricating a semiconductor device that includes forming a mask layer over a substrate, forming a dummy layer having a first dummy feature and a second dummy feature over the mask layer, forming first and second spacer roofs to cover a top portion of the first and second dummy features, respectively, and forming first and second spacer sleeves to encircle side portions of the first and second dummy features, respectively, removing the first spacer roof and the first dummy feature while protecting the second dummy feature, removing a first end portion and a second end portion of the first spacer sleeve to form spacer fins, and patterning the mask layer using the spacer fins as a first mask element and the second dummy feature as a second mask element. | 08-12-2010 |
| 20100264468 | Method Of Fabrication Of A FinFET Element - The present disclosure provides a FinFET element and method of fabricating a FinFET element. The FinFET element includes a germanium-FinFET element (e.g., a multi-gate device including a Ge-fin). In one embodiment, the method of fabrication the Ge-FinFET element includes forming silicon fins on a substrate and selectively growing an epitaxial layer including germanium on the silicon fins. A Ge-condensation process may then be used to selectively oxidize the silicon of the Si-fin and transform the Si-fin to a Ge-fin. The method of fabrication provided may allow use of SOI substrate or bulk silicon substrates, and CMOS-compatible processes to form the Ge-FinFET element. | 10-21-2010 |
| 20100314687 | METAL GATE TRANSISTOR, INTEGRATED CIRCUITS, SYSTEMS, AND FABRICATION METHODS THEREOF - A gate-last method for forming a metal gate transistor is provided. The method includes forming an opening within a dielectric material over a substrate. A gate dielectric structure is formed within the opening and over the substrate. A work function metallic layer is formed within the opening and over the gate dielectric structure. A silicide structure is formed over the work function metallic layer. | 12-16-2010 |
| 20100317184 | METHOD FOR REDUCING INTERFACIAL LAYER THICKNESS FOR HIGH-K AND METAL GATE STACK - A method for reducing interfacial layer (IL) thickness for high-k dielectrics and metal gate stack is provided. In one embodiment, the method includes forming an interfacial layer on a semiconductor substrate, etching back the interfacial layer, depositing a high-k dielectric material over the interfacial layer, and forming a metal gate over the high-k dielectric material. The IL can be chemical oxide, ozonated oxide, thermal oxide, or formed by ultraviolet ozone (UVO) oxidation process from chemical oxide, etc. The etching back of IL can be performed by a Diluted HF (DHF) process, a vapor HF process, or any other suitable process. The method can further include performing UV curing or low thermal budget annealing on the interfacial layer before depositing the high-k dielectric material. | 12-16-2010 |
| 20110024804 | METHOD FOR FORMING HIGH GERMANIUM CONCENTRATION SIGE STRESSOR - A method for producing a SiGe stressor with high Ge concentration is provided. The method includes providing a semiconductor substrate with a source area, a drain area, and a channel in between; depositing the first SiGe film layer on the source area and/or the drain area; performing a low temperature thermal oxidation, e.g., a high water vapor pressure wet oxidation, to form an oxide layer at the top of the first SiGe layer and to form the second SiGe film layer with high Ge percentage at the bottom of the first SiGe film layer without Ge diffusion into the semiconductor substrate; performing a thermal diffusion to form the SiGe stressor from the second SiGe film layer, wherein the SiGe stressor provides uniaxial compressive strain on the channel; and removing the oxide layer. A Si cap layer can be deposited on the first SiGe film layer prior to performing oxidation. | 02-03-2011 |
| 20110062526 | METAL GATE TRANSISTOR, INTEGRATED CIRCUITS, SYSTEMS, AND FABRICATION METHODS THEREOF - A gate-last method for forming a metal gate transistor is provided. The method includes forming an opening within a dielectric material over a substrate. A gate dielectric structure is formed within the opening and over the substrate. A work function metallic layer is formed within the opening and over the gate dielectric structure. A silicide structure is formed over the work function metallic layer. | 03-17-2011 |
| 20110101421 | METHOD OF FORMING EPI FILM IN SUBSTRATE TRENCH - The present disclosure provides a method of fabricating a semiconductor device that includes providing a semiconductor substrate, forming a trench in the substrate, where a bottom surface of the trench has a first crystal plane orientation and a side surface of the trench has a second crystal plane orientation, and epitaxially (epi) growing a semiconductor material in the trench. The epi process utilizes an etch component. A first growth rate on the first crystal plane orientation is different from a second growth rate on the second crystal plane orientation. | 05-05-2011 |
| 20110151359 | INTEGRATED CIRCUIT LAYOUT DESIGN - Provided is a photolithography apparatus including a photomask. The photomask includes a pattern having a plurality, of features, in an example, dummy line features. The pattern includes a first region being in the form of a localized on-grid array and a second region where at least one of the features has an increased width. The apparatus may include a second photomask which may define an active region. The feature with an increased width may be adjacent, and outside, the defined active region. | 06-23-2011 |
