Patent application number | Description | Published |
20080265282 | SILICON GERMANIUM HETEROJUNCTION BIPOLAR TRANSISTOR STRUCTURE AND METHOD - Disclosed is an improved semiconductor structure (e.g., a silicon germanium (SiGe) hetero-junction bipolar transistor) having a narrow essentially interstitial-free SIC pedestal with minimal overlap of the extrinsic base. Also, disclosed is a method of forming the transistor which uses laser annealing, as opposed to rapid thermal annealing, of the SIC pedestal to produce both a narrow SIC pedestal and an essentially interstitial-free collector. Thus, the resulting SiGe HBT transistor can be produced with narrower base and collector space-charge regions than can be achieved with conventional technology. | 10-30-2008 |
20090001470 | METHOD FOR FORMING ACUTE-ANGLE SPACER FOR NON-ORTHOGONAL FINFET AND THE RESULTING STRUCTURE - In a method of fabricating a semiconductor finFET transistor for an integrated circuit chip comprising 1) the formation of at least one fin body on the surface of a substrate and 2) the formation of a gate on said fin body in a non-orthogonal orientation relative to the body thereby creating acute angle regions at the crossover of the gate on the body, and 3) the formation of a protective material in the acute angle regions so as to prevent damage to the gate during subsequent fabrication steps. The structure of the finFET transistor comprises such a transistor with protective material in the acute angle regions at the crossover of the gate on the body. | 01-01-2009 |
20090065817 | DIELECTRIC SPACER REMOVAL - The present invention relates to semiconductor devices, and more particularly to a process and structure for removing a dielectric spacer selective to a surface of a semiconductor substrate with substantially no removal of the semiconductor substrate. The method of the present invention can be integrated into a conventional CMOS processing scheme or into a conventional BiCMOS processing scheme. The method includes forming a field effect transistor on a semiconductor substrate, the FET comprising a dielectric spacer and the gate structure, the dielectric spacer located adjacent a sidewall of the gate structure and over a source/drain region in the semiconductor substrate; depositing a first nitride layer over the FET; and removing the nitride layer and the dielectric spacer selective to the semiconductor substrate with substantially no removal of the semiconductor substrate. | 03-12-2009 |
20090081836 | METHOD OF FORMING CMOS WITH SI:C SOURCE/DRAIN BY LASER MELTING AND RECRYSTALLIZATION - A method of forming crystalline Si:C in source and drain regions is provided. After formation of shallow trench isolation and gate electrodes of field effect transistors, gate spacers are formed on gate electrodes. Preamorphization implantation is performed in the source and drain regions, followed by carbon implantation. The upper portion of the source and drain regions comprises an amorphous mixture of silicon, germanium, and/or carbon. An anti-reflective layer is deposited to enhance the absorption of a laser beam into the silicon substrate. The laser beam is scanned over the silicon substrate including the upper source and drain region with the amorphous mixture. The energy of the laser beam is controlled so that the temperature of the semiconductor substrate is above the melting temperature of the amorphous mixture but below the glass transition temperature of silicon oxide so that structural integrity of the semiconductor structure is preserved. | 03-26-2009 |
20090108300 | SILICON GERMANIUM HETEROJUNCTION BIPOLAR TRANSISTOR STRUCTURE AND METHOD - Disclosed is a design structure for an improved semiconductor structure (e.g., a silicon germanium (SiGe) hetero-junction bipolar transistor) having a narrow essentially interstitial-free SIC pedestal with minimal overlap of the extrinsic base. Also, disclosed is a method of forming the transistor which uses laser annealing, as opposed to rapid thermal annealing, of the SIC pedestal to produce both a narrow SIC pedestal and an essentially interstitial-free collector. Thus, the resulting SiGe HBT transistor can be produced with narrower base and collector space-charge regions than can be achieved with conventional technology. | 04-30-2009 |
20090174002 | MOSFET HAVING A HIGH STRESS IN THE CHANNEL REGION - Source and drain extension regions are selectively removed by a dopant concentration dependent etch or a doping type dependent etch, and an embedded stress-generating material such as SiGe alloy or a Si:C alloy in the source and drain extension regions is grown on a semiconductor substrate. The embedded stress-generating material may be grown only in the source and drain extension regions, or in the source and drain extension regions and in deep source and drain regions. In one embodiment, an etch process that removes doped semiconductor regions of one conductivity type selective to doped semiconductor regions of another conductivity type may be employed. In another embodiment, a dopant concentration dependent etch process that removes doped semiconductor regions irrespective of the conductivity type selective to undoped semiconductor regions may be employed. | 07-09-2009 |
20090186455 | DISPOSABLE METALLIC OR SEMICONDUCTOR GATE SPACER - A disposable spacer is formed directly on or in close proximity to the sidewalls of a gate electrode and a gate dielectric. The disposable spacer comprises a material that scavenges oxygen such as a metal, a metal nitride, or a semiconductor material having high reactivity with oxygen. The disposable gate spacer absorbs any oxygen during subsequent high temperature processing such as a stress memorization anneal. A metal is deposited over, and reacted with, the gate electrode and source and drain regions to form metal semiconductor alloy regions. The disposable gate spacer is subsequently removed selective to the metal semiconductor alloy regions. A porous or non-porous low-k dielectric material is deposited to provide a low parasitic capacitance between the gate electrode and the source and drain regions. The gate dielectric maintains the original dielectric constant since the disposable gate spacer prevents absorption of additional oxygen during high temperature processes. | 07-23-2009 |
20090191679 | LOCAL STRESS ENGINEERING FOR CMOS DEVICES - A first dielectric layer is formed over a PFET gate and an NFET gate, and lithographically patterned to expose a PFET area, while covering an NFET area. Exposed PFET active area is etched and refilled with a SiGe alloy, which applies a uniaxial compressive stress to a PFET channel. A second dielectric layer is formed over the PFET gate and the NFET gate, and lithographically patterned to expose the NFET area, while covering the PFET area. Exposed NFET active area is etched and refilled with a silicon-carbon alloy, which applies a uniaxial tensile stress to an NFET channel. Dopants may be introduced into the SiGe and silicon-carbon regions by in-situ doping or by ion implantation. | 07-30-2009 |
20090243031 | STRUCTURE AND METHOD TO CONTROL OXIDATION IN HIGH-K GATE STRUCTURES - In one embodiment, the present invention provides a method of fabricating a semiconducting device that includes providing a substrate including at least one semiconducting region and at least one oxygen source region; forming an oxygen barrier material atop portions of an upper surface of the at least one oxygen region; forming a high-k gate dielectric on the substrate including the at least one semiconducting region, wherein oxygen barrier material separates the high-k gate dielectric from the at least one oxygen source material; and forming a gate conductor atop the high-k gate dielectric. | 10-01-2009 |
20100159664 | SILICON GERMANIUM HETEROJUNCTION BIPOLAR TRANSISTOR STRUCTURE AND METHOD - Disclosed is an improved semiconductor structure (e.g., a silicon germanium (SiGe) hetero-junction bipolar transistor) having a narrow essentially interstitial-free SIC pedestal with minimal overlap of the extrinsic base. Also, disclosed is a method of forming the transistor which uses laser annealing, as opposed to rapid thermal annealing, of the SIC pedestal to produce both a narrow SIC pedestal and an essentially interstitial-free collector. Thus, the resulting SiGe HBT transistor can be produced with narrower base and collector space-charge regions than can be achieved with conventional technology. | 06-24-2010 |
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 |
20120104507 | METHOD FOR GROWING STRAIN-INDUCING MATERIALS IN CMOS CIRCUITS IN A GATE FIRST FLOW - A method of manufacturing a complementary metal oxide semiconductor (CMOS) circuit, in which the method includes a reactive ion etch (RIE) of a CMOS circuit substrate that forms recesses, the CMOS circuit substrate including: an n-type field effect transistor (n-FET) region; a p-type field effect transistor (p-FET) region; an isolation region disposed between the n-FET and p-FET regions; and a gate wire comprising an n-FET gate, a p-FET gate, and gate material extending transversely from the n-FET gate across the isolation region to the p-FET gate, in which the recesses are formed adjacent to sidewalls of a reduced thickness; growing silicon germanium (SiGe) in the recesses; depositing a thin insulator layer on the CMOS circuit substrate; masking at least the p-FET region; removing the thin insulator layer from an unmasked n-FET region and an unmasked portion of the isolation region; etching the CMOS circuit substrate with hydrogen chloride (HCl) to remove the SiGe from the recesses in the n-FET region; and growing silicon carbon (SiC) in the exposed recesses. | 05-03-2012 |
20120248436 | REDUCED PATTERN LOADING FOR DOPED EPITAXIAL PROCESS AND SEMICONDUCTOR STRUCTURE - A semiconductor substrate having transistor structures and test structures with spacing between the transistor structures smaller than the spacing between the test structures is provided. A first iteratively performed deposition and etch process includes: depositing a first doped epitaxial layer having a first concentration of a dopant over the semiconductor substrate, and etching the first doped epitaxial layer. A second iteratively performed deposition and etch process includes: depositing a second doped epitaxial layer having a second concentration of the dopant higher than the first concentration over the semiconductor substrate, and etching the second doped epitaxial layer. The first concentration results in a first net growth rate over the transistor structures and the second concentration results in a lower, second net growth rate over the test structures than the transistor structures, resulting in reduced pattern loading. | 10-04-2012 |
20120319110 | SEMICONDUCTOR STRUCTURE HAVING TEST AND TRANSISTOR STRUCTURES - A semiconductor substrate having transistor structures and test structures with spacing between the transistor structures smaller than the spacing between the test structures is provided. A first iteratively performed deposition and etch process includes: depositing a first doped epitaxial layer having a first concentration of a dopant over the semiconductor substrate, and etching the first doped epitaxial layer. A second iteratively performed deposition and etch process includes: depositing a second doped epitaxial layer having a second concentration of the dopant higher than the first concentration over the semiconductor substrate, and etching the second doped epitaxial layer. The first concentration results in a first net growth rate over the transistor structures and the second concentration results in a lower, second net growth rate over the test structures than the transistor structures, resulting in reduced pattern loading. | 12-20-2012 |
20130095631 | BIPOLAR TRANSISTOR WITH LOW RESISTANCE BASE CONTACT AND METHOD OF MAKING THE SAME - Embodiments of the present invention provide a bipolar transistor with low resistance base contact and method of manufacturing the same. The bipolar transistor includes an emitter, a collector, and an intrinsic base between the emitter and the collector. The intrinsic base extends laterally to an extrinsic base. The extrinsic base further includes a first semiconductor material with a first bandgap and a second semiconductor material with a second bandgap that is smaller than the first bandgap. | 04-18-2013 |
20130161759 | METHOD FOR GROWING STRAIN-INDUCING MATERIALS IN CMOS CIRCUITS IN A GATE FIRST FLOW - A complementary metal oxide semiconductor (CMOS) circuit incorporating a substrate and a gate wire over the substrate. The substrate comprises an n-type field effect transistor (n-FET) region, a p-type field effect transistor (p-FET) region and an isolation region disposed between the n-FET and p-FET regions. The gate wire comprises an n-FET gate, a p-FET gate, and gate material extending transversely from the n-FET gate across the isolation region to the p-FET gate. A first conformal insulator covers the gate wire and a second conformal insulator is on the first conformal insulator positioned over the p-FET gate without extending laterally over the n-FET gate. Straining regions for producing different types of strain are formed in recess etched into the n-FET and p-FET regions of the substrate. | 06-27-2013 |
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 |
20130210210 | SILICON GERMANIUM HETEROJUNCTION BIPOLAR TRANSISTOR STRUCTURE AND METHOD - Disclosed is an improved semiconductor structure (e.g., a silicon germanium (SiGe) hetero-junction bipolar transistor) having a narrow essentially interstitial-free SIC pedestal with minimal overlap of the extrinsic base. Also, disclosed is a method of forming the transistor which uses laser annealing, as opposed to rapid thermal annealing, of the SIC pedestal to produce both a narrow SIC pedestal and an essentially interstitial-free collector. Thus, the resulting SiGe HBT transistor can be produced with narrower base and collector space-charge regions than can be achieved with conventional technology. | 08-15-2013 |
20140306290 | Dual Silicide Process Compatible with Replacement-Metal-Gate - In one aspect, a method for fabricating an electronic device includes the following steps. A wafer is provided having at least one first active area and at least one second active area defined therein. One or more p-FET/n-FET devices are formed in the active areas, each having a p-FET/n-FET gate stack and p-FET/n-FET source and drain regions. A self-aligned silicide is formed in each of the p-FET/n-FET source and drain regions, wherein the self-aligned silicide in each of the p-FET source and drain regions has a thickness T1 and the self-aligned silicide in each of the n-FET source and drain regions having a thickness T2, wherein T1 is less than T2. During a subsequent trench silicidation in the p-FET/n-FET source and drain regions, the trench silicide metal will diffuse through the thinner self-aligned silicide in the p-FET device(s) but not through the thicker self-aligned silicide in the n-FET device(s). | 10-16-2014 |
20140306291 | Dual Silicide Process Compatible with Replacement-Metal-Gate - In one aspect, a method for fabricating an electronic device includes the following steps. A wafer is provided having at least one first active area and at least one second active area defined therein. One or more p-FET/n-FET devices are formed in the active areas, each having a p-FET/n-FET gate stack and p-FET/n-FET source and drain regions. A self-aligned silicide is formed in each of the p-FET/n-FET source and drain regions, wherein the self-aligned silicide in each of the p-FET source and drain regions has a thickness T1 and the self-aligned silicide in each of the n-FET source and drain regions having a thickness T2, wherein T1 is less than T2. During a subsequent trench silicidation in the p-FET/n-FET source and drain regions, the trench silicide metal will diffuse through the thinner self-aligned silicide in the p-FET device(s) but not through the thicker self-aligned silicide in the n-FET device(s). | 10-16-2014 |