| 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 |
| 20080206951 | HIGH PERFORMANCE FIELD EFFECT TRANSISTORS ON SOI SUBSTRATE WITH STRESS-INDUCING MATERIAL AS BURIED INSULATOR AND METHODS - The present invention provides a semiconductor structure that includes a high performance field effect transistor (FET) on a semiconductor-on-insulator (SOI) in which the insulator thereof is a stress-inducing material of a preselected geometry. Such a structure achieves performance enhancement from uniaxial stress, and the stress in the channel is not dependent on the layout design of the local contacts. In broad terms, the present invention relates to a semiconductor structure that comprises an upper semiconductor layer and a bottom semiconductor layer, wherein said upper semiconductor layer is separated from said bottom semiconductor layer in at least one region by a stress-inducing insulator having a preselected geometric shape, said stress-inducing insulator exerting a strain on the upper semiconductor layer. | 08-28-2008 |
| 20080251817 | STRESSED FIELD EFFECT TRANSISTORS ON HYBRID ORIENTATION SUBSTRATE - A semiconductor structure having improved carrier mobility is provided. The semiconductor structures includes a hybrid oriented semiconductor substrate having at least two planar surfaces of different crystallographic orientation, and at least one CMOS device located on each of the planar surfaces of different crystallographic orientation, wherein each CMOS device has a stressed channel. The present invention also provides methods of fabricating the same. In general terms, the inventive method includes providing a hybrid oriented substrate having at least two planar surfaces of different crystallographic orientation, and forming at least one CMOS device on each of the planar surfaces of different crystallographic orientation, wherein each CMOS device has a stressed channel. | 10-16-2008 |
| 20080258180 | CROSS-SECTION HOURGLASS SHAPED CHANNEL REGION FOR CHARGE CARRIER MOBILITY MODIFICATION - A semiconductor structure and a method for fabricating the semiconductor structure include a semiconductor substrate having a cross-section hourglass shaped channel region. A stress imparting layer is located adjacent the channel region. The hourglass shape may provide for enhanced vertical tensile stress within the channel region when it is longitudinally compressive stressed by the stress imparting layer. | 10-23-2008 |
| 20080268609 | STACKING FAULT REDUCTION IN EPITAXIALLY GROWN SILICON - Methods are disclosed for providing stacking fault reduced epitaxially grown silicon for use in hybrid surface orientation structures. In one embodiment, a method includes depositing a silicon nitride liner over a silicon oxide liner in an opening, etching to remove the silicon oxide liner and silicon nitride liner on a lower surface of the opening, undercutting the silicon nitride liner adjacent to the lower surface, and epitaxially growing silicon in the opening. The silicon is substantially reduced of stacking faults because of the negative slope created by the undercut. | 10-30-2008 |
| 20090029531 | HYBRID ORIENTATION SUBSTRATE AND METHOD FOR FABRICATION THEREOF - A method for fabricating a hybrid orientation substrate provides for: (1) a horizontal epitaxial augmentation of a masked surface semiconductor layer that leaves exposed a portion of a base semiconductor substrate; and (2) a vertical epitaxial augmentation of the exposed portion of the base semiconductor substrate. The resulting surface semiconductor layer and epitaxial surface semiconductor layer adjoin with an interface that is not perpendicular to the base semiconductor substrate. The method also includes implanting through the surface semiconductor layer and the epitaxial surface semiconductor layer a dielectric forming ion to provide a buried dielectric layer that separates the surface semiconductor layer and the epitaxial surface semiconductor layer from the base semiconductor substrate. | 01-29-2009 |
| 20090108302 | MULTIPLE CRYSTALLOGRAPHIC ORIENTATION SEMICONDUCTOR STRUCTURES - A semiconductor structure includes an epitaxial surface semiconductor layer having a first dopant polarity and a first crystallographic orientation, and a laterally adjacent semiconductor-on-insulator surface semiconductor layer having a different second dopant polarity and different second crystallographic orientation. The epitaxial surface semiconductor layer has a first edge that has a defect and an adjoining second edge absent a defect. Located within the epitaxial surface semiconductor layer is a first device having a first gate perpendicular to the first edge and a second device having a second gate perpendicular to the second edge. The first device may comprise a performance sensitive logic device and the second device may comprise a yield sensitive memory device. An additional semiconductor structure includes a further laterally adjacent second semiconductor-on-insulator surface semiconductor layer having the first polarity and the second crystallographic orientation, and absent edge defects, to accommodate yield sensitive devices. | 04-30-2009 |
| 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 |
| 20090173941 | METHOD FOR FABRICATING A SEMICONDUCTOR STRUCTURES AND STRUCTURES THEREOF - Methods of fabricating a semiconductor structure with a non-epitaxial thin film disposed on a surface of a substrate of the semiconductor structure; and semiconductor structures formed thereof are disclosed. The methods provide selective non-epitaxial growth (SNEG) or deposition of amorphous and/or polycrystalline materials to form a thin film on the surface thereof. The surface may be a non-crystalline dielectric material or a crystalline material. The SNEG on non-crystalline dielectric further provides selective growth of amorphous/polycrystalline materials on nitride over oxide through careful selection of precursors-carrier-etchant ratio. The non-epitaxial thin film forms resultant and/or intermediate semiconductor structures that may be incorporated into any front-end-of-the-line (FEOL) fabrication process. Such resultant/intermediate structures may be used, for example, but are not limited to: source-drain fabrication; hardmask strengthening; spacer widening; high-aspect-ratio (HAR) vias filling; micro-electro-mechanical-systems (MEMS) fabrication; FEOL resistor fabrication; lining of shallow trench isolations (STI) and deep trenches; critical dimension (CD) tailoring and claddings. | 07-09-2009 |
| 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 |
| 20090302348 | STRESS ENHANCED TRANSISTOR DEVICES AND METHODS OF MAKING - Stress enhanced transistor devices and methods of fabricating the same are provided. In one embodiment, a transistor device comprises: a gate conductor disposed above a semiconductor substrate between a pair of dielectric spacers, wherein the semiconductor substrate comprises a channel region underneath the gate conductor and recessed regions on opposite sides of the channel region, wherein the recessed regions undercut the dielectric spacers to form undercut areas of the channel region; and epitaxial source and drain regions disposed in the recessed regions of the semiconductor substrate and extending laterally underneath the dielectric spacers into the undercut areas of the channel region. | 12-10-2009 |
| 20100009502 | Semiconductor Fabrication Process Including An SiGe Rework Method - A method for fabricating a semiconductor device includes forming an SiGe region. The SiGe region can be an embedded source and drain region, or a compressive SiGe channel layer, or other SiGe regions within a semiconductor device. The SiGe region is exposed to an SC1 solution and excess surface portions of the SiGe region are selectively removed. The SC1 etching process can be part of a rework method in which overgrowth regions of SiGe are selectively removed by exposing the SiGe to and SC1 solution maintained at an elevated temperature. The etching process is carried out for a period of time sufficient to remove excess surface portions of SiGe. The SC1 etching process can be carried out at elevated temperatures ranging from about 25° C. to about 65° C. | 01-14-2010 |
| 20100090288 | METHOD OF FORMING SOURCE AND DRAIN OF A FIELD-EFFECT-TRANSISTOR AND STRUCTURE THEREOF - A semiconductor fabrication method involving the use of eSiGe is disclosed. The eSiGe approach is useful for applying the desired stresses to the channel region of a field effect transistor, but also can introduce complications into the semiconductor fabrication process. Embodiments of the present invention disclose a two-step fabrication process in which a first layer of eSiGe is applied using a low hydrogen flow rate, and a second eSiGe layer is applied using a higher hydrogen flow rate. This method provides a way to balance the tradeoff of morphology, and fill consistency when using eSiGe. Embodiments of the present invention promote a pinned morphology, which reduces device sensitivity to epitaxial thickness, while also providing a more consistent fill volume, amongst various device widths, thereby providing a more consistent eSiGe semiconductor fabrication process. | 04-15-2010 |
| 20100112762 | METHOD FOR FABRICATING SEMICONDUCTOR STRUCTURES - Methods of fabricating a semiconductor structure with a non- epitaxial thin film disposed on a surface of a substrate of the semiconductor structure are disclosed. The methods provide selective non-epitaxial growth (SNEG) or deposition of amorphous and/or polycrystalline materials to form a thin film on the surface thereof. The surface may be a non-crystalline dielectric material or a crystalline material. The SNEG on non-crystalline dielectric further provides selective growth of amorphous/polycrystalline materials on nitride over oxide through careful selection of precursors-carrier-etchant ratio. The non-epitaxial thin film forms resultant and/or intermediate semiconductor structures that may be incorporated into any front-end-of-the-line (FEOL) fabrication process. Such resultant/intermediate structures may be used, for example, but are not limited to: source-drain fabrication; hardmask strengthening; spacer widening; high-aspect-ratio (HAR) vias filling; micro-electro-mechanical-systems (MEMS) fabrication; FEOL resistor fabrication; lining of shallow trench isolations (STI) and deep trenches; critical dimension (CD) tailoring and claddings. | 05-06-2010 |
| 20100187578 | STRESS ENHANCED TRANSISTOR DEVICES AND METHODS OF MAKING - Stress enhanced transistor devices and methods of fabricating the same are disclosed. In one embodiment, a transistor device comprises: a gate conductor spaced above a semiconductor substrate by a gate dielectric, wherein the semiconductor substrate comprises a channel region underneath the gate conductor and recessed regions on opposite sides of the channel region, wherein the channel region comprises undercut areas under the gate conductor; a stressed material embedded in the undercut areas of the channel region under the gate conductor; and epitaxially grown source and drain regions disposed in the recessed regions of the semiconductor substrate laterally adjacent to the stressed material. | 07-29-2010 |
| 20100197118 | MULTIPLE CRYSTALLOGRAPHIC ORIENTATION SEMICONDUCTOR STRUCTURES - A semiconductor structure includes an epitaxial surface semiconductor layer having a first dopant polarity and a first crystallographic orientation, and a laterally adjacent semiconductor-on-insulator surface semiconductor layer having a different second dopant polarity and different second crystallographic orientation. The epitaxial surface semiconductor layer has a first edge that has a defect and an adjoining second edge absent a defect. Located within the epitaxial surface semiconductor layer is a first device having a first gate perpendicular to the first edge and a second device having a second gate perpendicular to the second edge. The first device may include a performance sensitive logic device and the second device may include a yield sensitive memory device. An additional semiconductor structure includes a further laterally adjacent second semiconductor-on-insulator surface semiconductor layer having the first polarity and the second crystallographic orientation, and absent edge defects, to accommodate yield sensitive devices. | 08-05-2010 |
| 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 |
| 20100283089 | METHOD OF REDUCING STACKING FAULTS THROUGH ANNEALING - Accordingly, in one embodiment of the invention, a method is provided for reducing stacking faults in an epitaxial semiconductor layer. In accordance with such method, a substrate is provided which includes a first single-crystal semiconductor region including a first semiconductor material, the first semiconductor region having a <110> crystal orientation. An epitaxial layer including the first semiconductor material is grown on the first semiconductor region, the epitaxial layer having the <110> crystal orientation. The substrate is then annealed with the epitaxial layer at a temperature greater than 1100 degrees Celsius in an ambient including hydrogen, whereby the step of annealing reduces stacking faults in the epitaxial layer. | 11-11-2010 |
| 20110159655 | STRESS ENHANCED TRANSISTOR DEVICES AND METHODS OF MAKING - Stress enhanced transistor devices and methods of fabricating the same are provided. In one embodiment, a transistor device comprises: a gate conductor disposed above a semiconductor substrate between a pair of dielectric spacers, wherein the semiconductor substrate comprises a channel region underneath the gate conductor and recessed regions on opposite sides of the channel region, wherein the recessed regions undercut the dielectric spacers to form undercut areas of the channel region; and epitaxial source and drain regions disposed in the recessed regions of the semiconductor substrate and extending laterally underneath the dielectric spacers into the undercut areas of the channel region. | 06-30-2011 |
