| Patent application number | Description | Published |
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| 20080199998 | PRE-EPITAXIAL DISPOSABLE SPACER INTEGRATION SCHEME WITH VERY LOW TEMPERATURE SELECTIVE EPITAXY FOR ENHANCED DEVICE PERFORMANCE - The embodiments of the invention provide a method, etc. for a pre-epitaxial disposable spacer integration scheme with very low temperature selective epitaxy for enhanced device performance. More specifically, one method begins by forming a first gate and a second gate on a substrate. Next, an oxide layer is formed on the first and second gates; and, a nitride layer is formed on the oxide layer. Portions of the nitride layer proximate the first gate, portions of the oxide layer proximate the first gate, and portions of the substrate proximate the first gate are removed so as to form source and drain recesses proximate the first gate. Following this, the method removes remaining portions of the nitride layer, including exposing remaining portions of the oxide layer. The removal of the remaining portions of the nitride layer only exposes the remaining portions of the oxide layer and the source and drain recesses. | 08-21-2008 |
| 20080224258 | SEMICONDUCTOR STRUCTUE WITH MULTIPLE FINS HAVING DIFFERENT CHANNEL REGION HEIGHTS AND METHOD OF FORMING THE SEMICONDUCTOR STRUCTURE - Disclosed are embodiments of a semiconductor structure with fins that are positioned on the same planar surface of a wafer and that have channel regions with different heights. In one embodiment the different channel region heights are accomplished by varying the overall heights of the different fins. In another embodiment the different channel region heights are accomplished by varying, not the overall heights of the different fins, but rather by varying the heights of a semiconductor layer within each of the fins. The disclosed semiconductor structure embodiments allow different multi-gate non-planar FETs (i.e., tri-gate or dual-gate FETs) with different effective channel widths to be formed of the same wafer and, thus, allows the beta ratio in devices that incorporate multiple FETs (e.g., static random access memory (SRAM) cells) to be selectively adjusted. | 09-18-2008 |
| 20080265281 | EMBEDDED SILICON GERMANIUM USING A DOUBLE BURIED OXIDE SILICON-ON-INSULATOR WAFER - Disclosed is a p-type field effect transistor (pFET) structure and method of forming the pFET. The pFET comprises embedded silicon germanium in the source/drain regions to increase longitudinal stress on the p-channel and, thereby, enhance transistor performance. Increased stress is achieved by increasing the depth of the source/drain regions and, thereby, the volume of the embedded silicon germanium. The greater depth (e.g., up to 100 nm) of the stressed silicon germanium source/drain regions is achieved by using a double BOX SOI wafer. Trenches are etched through a first silicon layer and first buried oxide layer and then the stressed silicon germanium is epitaxially grown from a second silicon layer. A second buried oxide layer isolates the pFET. | 10-30-2008 |
| 20090092810 | FABRICATION OF SOI WITH GETTERING LAYER - An SOI substrate has a gettering layer of silicon-germanium (SiGe) with 5-10% Ge, and a thickness of approximately 50-1000 nm. Carbon (C) may be added to SiGe to stabilize the dislocation network. The SOI substrate may be a SIMOX SOI substrate, or a bonded SOI substrate, or a seeded SOI substrate. The gettering layer may disposed under a buried oxide (BOX) layer. The gettering layer may be disposed on a backside of the substrate. | 04-09-2009 |
| 20090102026 | SEMICONDUCTOR-ON-INSULATOR SUBSTRATE WITH A DIFFUSION BARRIER - A diffusion barrier layer is incorporated between a top semiconductor layer and buried oxide layer. The diffusion barrier layer blocks diffusion of dopants into or out of buried oxide layer. The diffusion barrier layer may comprise a dielectric material such as silicon oxynitride or a high-k gate dielectric material. Alternately, the diffusion barrier layer may comprise a semiconductor material such as SiC. Such materials provide less charge trapping than a silicon nitride layer, which causes a high level of interface trap density and charge in the buried oxide layer. Thus, diffusion of dopants from and into semiconductor devices through the buried oxide layer is suppressed by the diffusion barrier layer without inducing a high interface trap density or charge in the buried oxide layer. | 04-23-2009 |
| 20090152590 | METHOD AND STRUCTURE FOR SEMICONDUCTOR DEVICES WITH SILICON-GERMANIUM DEPOSITS - A method of forming a semiconductor device including forming a second deposit of silicon-germanium on a first deposit of silicon-germanium, the first deposit formed in a conduction terminal region of a substrate of the semiconductor device and having a first percentage of germanium, and the second deposit having a second percentage of germanium that is less than the first percentage and supports forming a silicide deposit on the second deposit. A structure is also provided. | 06-18-2009 |
| 20090267118 | METHOD FOR FORMING CARBON SILICON ALLOY (CSA) AND STRUCTURES THEREOF - Methods for forming carbon silicon alloy (CSA) and structures thereof are disclosed. The method provides improvement in substitutionality and deposition rate of carbon in epitaxially grown carbon silicon alloy layers (i.e., substituted carbon in Si lattice). In one embodiment of the disclosed method, a carbon silicon alloy layer is epitaxially grown on a substrate at an intermediate temperature with a silicon precursor, a carbon (C) precursor in the presence of an etchant and a trace amount of germanium material (e.g., germane (GeH | 10-29-2009 |
| 20090269926 | POLYGRAIN ENGINEERING BY ADDING IMPURITIES IN THE GAS PHASE DURING CHEMICAL VAPOR DEPOSITION OF POLYSILICON - A method of forming at least one gate conductor of a complementary metal oxide semiconductor performs a chemical vapor deposition process of polysilicon over a surface where a polysilicon gate is to be located. This deposition can be performed through a mask to form gate structures directly, or a later patterning process can pattern the polysilicon into gate structures. During the chemical vapor deposition process, the method adds impurities in the chemical vapor deposition process to optimize the grain size of the polysilicon according to a number of different methods. | 10-29-2009 |
| 20090294801 | METHODS OF INTEGRATING REVERSE eSiGe ON NFET AND SiGe CHANNEL ON PFET, AND RELATED STRUCTURE - Methods of integrating reverse embedded silicon germanium (SiGe) on an NFET and SiGe channel on a PFET, and a related structure are disclosed. One method may include providing a substrate including an NFET area and a PFET area; performing a single epitaxial growth of a silicon germanium (SiGe) layer over the substrate; forming an NFET in the NFET area, the NFET including a SiGe plug in a channel thereof formed from the SiGe layer; and forming a PFET in the PFET area, the PFET including a SiGe channel formed from the SiGe layer. As an option, the SiGe layer over the PFET area may be thinned. | 12-03-2009 |
| 20100035419 | PATTERN INDEPENDENT Si:C SELECTIVE EPITAXY - Trenches are formed in a silicon substrate by etching exposed portions of the silicon substrate. After covering areas on which deposition of Si:C containing material is to be prevented, selective epitaxy is performed in a single wafer chamber at a temperature from about 550° C. to about 600° C. employing a limited carrier gas flow, i.e., at a flow rate less than 12 standard liters per minute to deposit Si:C containing regions at a pattern-independent uniform deposition rate. The inventive selective epitaxy process for Si:C deposition provides a relatively high net deposition rate a high quality Si:C crystal in which the carbon atoms are incorporated into substitutional sites as verified by X-ray diffraction. | 02-11-2010 |
| 20100200937 | METHOD AND STRUCTURE FOR PMOS DEVICES WITH HIGH K METAL GATE INTEGRATION AND SiGe CHANNEL ENGINEERING - Various techniques for changing the workfunction of the substrate by using a SiGe channel which, in turn, changes the bandgap favorably for a p-type metal oxide semiconductor field effect transistors (pMOSFETs) are disclosed. In the various techniques, a SiGe film that includes a low doped SiGe region above a more highly doped SiGe region to allow the appropriate threshold voltage (Vt) for pMOSFET devices while preventing pitting, roughness and thinning of the SiGe film during subsequent cleans and processing is provided. | 08-12-2010 |
