Patent application number | Description | Published |
20090053864 | METHOD FOR FABRICATING A SEMICONDUCTOR STRUCTURE HAVING HETEROGENEOUS CRYSTALLINE ORIENTATIONS - A method for fabricating a semiconductor structure having heterogeneous crystalline orientations by forming a region including a semiconductor material having a specified crystalline orientation using an epitaxial buffer overlying a semiconductor substrate. The buffer provides a transfer body such that the semiconductor material has a crystalline orientation that differs from the crystalline orientation of a semiconductor region underlying the buffer. The method also includes fabricating a semiconductor structure having a p-type device region and an n-type device region, where a supporting semiconductor substrate is either n-type or p-type and where the semiconductor material is separated from the substrate by a buffer and has a crystalline orientation that differs from the crystalline orientation of the substrate. | 02-26-2009 |
20090140292 | INTEGRATED CIRCUIT AND METHOD OF FABRICATION THEREOF - A method of forming an integrated circuit structure comprising the steps of forming a first and second device region on a surface of a wafer, forming a spacer of a first width on a sidewall of a first gate stack in the first device region, forming a spacer of a second width on a sidewall of a second gate stack in the second device region, with the first width being different from the second width. | 06-04-2009 |
20090146262 | INTEGRATED CIRCUIT SYSTEM EMPLOYING SELECTIVE EPITAXIAL GROWTH TECHNOLOGY - An integrated circuit system that includes: providing a substrate; depositing a dielectric on the substrate; depositing an isolation dielectric on the dielectric; forming a trench through the isolation dielectric and the dielectric to expose the substrate; depositing a dielectric liner over the integrated circuit system; processing the dielectric liner to form a trench spacer; and depositing an epitaxial growth within the trench that includes a crystalline orientation that is substantially identical to the substrate. | 06-11-2009 |
20090146296 | Method of forming high-k dielectric stop layer for contact hole opening - A composite etch stop layer which comprises primary and secondary stop layers is used to form contacts in a dielectric layer to contact regions in a substrate. The secondary etch stop layer includes a high-k dielectric material to achieve high etch selectivity with the dielectric layer during contact formation. The secondary stop layer is removed to expose the contact regions. Removal of the secondary stop layer is achieved with high selectivity to the materials therebelow. | 06-11-2009 |
20090194788 | STRAINED CHANNEL TRANSISTOR STRUCTURE AND METHOD - A transistor device structure comprising: a substrate portion formed from a first material; and a source region, a drain region and a channel region formed in said substrate, the source and drain regions comprising a plurality of islands of a second material different from the first material, the islands being arranged to induce a strain in said channel region of the substrate. | 08-06-2009 |
20090218597 | METHOD FOR FABRICATING A SEMICONDUCTOR DEVICE HAVING AN EPITAXIAL CHANNEL AND TRANSISTOR HAVING SAME - A transistor having an epitaxial channel and a method for fabricating a semiconductor device having an epitaxial channel, the method including forming a hardmask on a substrate and forming an opening in the hardmask. The opening is geometrically characterized by a long dimension and a short dimension, and the opening is arranged in a predetermined manner relative to the channel region of a transistor. An epitaxial material is formed in the opening that induces strain in substrate regions proximate to the epitaxial material. The epitaxial material is confined to the opening, such that an epitaxial channel is formed. A transistor is fabricated in proximity to the epitaxial channel, such that the strain induced in the substrate provides enhanced transistor performance. By confining the epitaxial material to a predefined channel in the substrate, plastic strain relaxation of the epitaxial material is minimized and a maximum amount of strain is induced in the substrate. | 09-03-2009 |
20090250762 | INTEGRATED CIRCUIT SYSTEM EMPLOYING SACRIFICIAL SPACERS - An integrated circuit system that includes: providing a substrate including a first device and a second device; configuring the first device and the second device to include a first spacer, a first liner made from a first dielectric layer, and a second spacer made from a sacrificial spacer material; forming a second dielectric layer over the integrated circuit system; forming a first device source/drain and a second device source/drain adjacent the second spacer and through the second dielectric layer; removing the second spacer without damaging the substrate; forming a third dielectric layer over the integrated circuit system before annealing; and forming a fourth dielectric layer over the integrated circuit system that promotes stress within the channel of the first device, the second device, or a combination thereof. | 10-08-2009 |
20090289309 | METHOD FOR REDUCING SILICIDE DEFECTS IN INTEGRATED CIRCUITS - A method for forming silicide contacts in integrated circuits (ICs) is described. A spacer pull-back etch is performed during the salicidation process to reduce the stress between the spacer and source/drain silicide contact at the spacer undercut. This prevents the propagation of surface defects into the substrate, thereby minimizing the occurrence of silicide pipe defects. The spacer pull-back etch can be performed after a first annealing step to form the silicide contacts. | 11-26-2009 |
20100019329 | Method and apparatus to reduce thermal variations within an integrated circuit die using thermal proximity correction - A method (and semiconductor device) of fabricating a semiconductor device utilizes a thermal proximity correction (TPC) technique to reduce the impact of thermal variations during anneal. Prior to actual fabrication, a location of interest (e.g., a transistor) within an integrated circuit design is determined and an effective thermal area around the location is defined. Thermal properties of structures intended to be fabricated within this area are used to calculate an estimated temperature that would be achieved at the location of interest from a given anneal process. If the estimated temperature is below or above a predetermined target temperature (or range), TPC is performed. Various TPC techniques may be performed, such as the addition of dummy cells and/or changing dimensions of the structure to be fabricated at the location of interest (resulting in an modified thermally corrected design, to suppress local variations in device performance caused by thermal variations during anneal. | 01-28-2010 |
20100096695 | HIGH STRESS FILM - A semiconductor device that includes a substrate having an active region prepared with a transistor is presented. The semiconductor device includes a stress structure adjacent to the substrate. The stress structure includes a dielectric layer having nanocrystals embedded therein. The nanocrystals induce a first or a second stress on a channel region of the transistor which improves carrier mobility of the transistor. | 04-22-2010 |
20100109045 | INTEGRATED CIRCUIT SYSTEM EMPLOYING STRESS-ENGINEERED LAYERS - An integrated circuit system that includes: providing a substrate including an active device; forming a trench within the substrate adjacent the active device; forming a first layer with a first lattice constant within the trench; and forming a second layer with a second lattice constant over the first layer, the second lattice constant differing from the first lattice constant. | 05-06-2010 |
20100221926 | LASER ANNEALING - A system for and method of processing an article such as a semiconductor wafer is disclosed. The wafer includes first and second surface which are segmented into a plurality of first and second zones. The first surface of the wafer, for example, on which devices or ICs are formed is processed by, for example, laser annealing while the second surface is heated with a backside heating source. Corresponding zones on the first and second surfaces are processed synchronously to reduce variations of post laser anneal thermal budge across the wafer. | 09-02-2010 |
20100267236 | METHOD FOR REDUCING SILICIDE DEFECTS IN INTEGRATED CIRCUITS - A method for forming silicide contacts in integrated circuits (ICs) is described. A spacer pull-back etch is performed during the salicidation process to reduce the stress between the spacer and source/drain silicide contact at the spacer undercut. This prevents the propagation of surface defects into the substrate, thereby minimizing the occurrence of silicide pipe defects. The spacer pull-back etch can be performed after a first annealing step to form the silicide contacts. | 10-21-2010 |
20100308374 | STRAINED CHANNEL TRANSISTOR STRUCTURE AND METHOD - A transistor device structure comprising: a substrate portion formed from a first material; and a source region, a drain region and a channel region formed in said substrate, the source and drain regions comprising a plurality of islands of a second material different from the first material, the islands being arranged to induce a strain in said channel region of the substrate. | 12-09-2010 |
20110281410 | METHOD FOR FABRICATING A SEMICONDUCTOR DEVICE HAVING AN EPITAXIAL CHANNEL AND TRANSISTOR HAVING SAME - A transistor having an epitaxial channel and a method for fabricating a semiconductor device having an epitaxial channel, the method including forming a hardmask on a substrate and forming an opening in the hardmask. The opening is geometrically characterized by a long dimension and a short dimension, and the opening is arranged in a predetermined manner relative to the channel region of a transistor. An epitaxial material is formed in the opening that induces strain in substrate regions proximate to the epitaxial material. The epitaxial material is confined to the opening, such that an epitaxial channel is formed. A transistor is fabricated in proximity to the epitaxial channel, such that the strain induced in the substrate provides enhanced transistor performance. By confining the epitaxial material to a predefined channel in the substrate, plastic strain relaxation of the epitaxial material is minimized and a maximum amount of strain is induced in the substrate. | 11-17-2011 |
20120012940 | INTEGRATED CIRCUIT AND METHOD OF FABRICATION THEREOF - A method of forming an integrated circuit structure comprising the steps of forming a first and second device region on a surface of a wafer, forming a spacer of a first width on a sidewall of a first gate stack in the first device region, forming a spacer of a second width on a sidewall of a second gate stack in the second device region, with the first width being different from the second width. | 01-19-2012 |
20130099321 | METHOD AND APPARATUS TO REDUCE THERMAL VARIATIONS WITHIN AN INTEGRATED CIRCUIT DIE USING THERMAL PROXIMITY CORRECTION - A method (and semiconductor device) of fabricating a semiconductor device utilizes a thermal proximity correction (TPC) technique to reduce the impact of thermal variations during anneal. Prior to actual fabrication, a location of interest (e.g., a transistor) within an integrated circuit design is determined and an effective thermal area around the location is defined. Thermal properties of structures intended to be fabricated within this area are used to calculate an estimated temperature that would be achieved at the location of interest from a given anneal process. If the estimated temperature is below or above a predetermined target temperature (or range), TPC is performed. Various TPC techniques may be performed, such as the addition of dummy cells and/or changing dimensions of the structure to be fabricated at the location of interest (resulting in an modified thermally corrected design, to suppress local variations in device performance caused by thermal variations during anneal. | 04-25-2013 |