Patent application number | Description | Published |
20090321786 | Band Gap Modulated Optical Sensor - A complementary metal-oxide-semiconductor (CMOS) optical sensor structure comprises a pixel containing a charge collection well of a same semiconductor material as a semiconductor layer in a semiconductor substrate and at least another pixel containing another charge collection well of a different semiconductor material than the material of the semiconductor layer. The charge collections wells have different band gaps, and consequently, generate charge carriers in response to light having different wavelengths. The CMOS sensor structure thus includes at least two pixels responding to light of different wavelengths, enabling wavelength-sensitive, or color-sensitive, capture of an optical data. Further, a design structure for the inventive complementary metal-oxide-semiconductor (CMOS) image sensor is also provided. | 12-31-2009 |
20090325337 | Band Gap Modulated Optical Sensor - A complementary metal-oxide-semiconductor (CMOS) optical sensor structure comprises a pixel containing a charge collection well of a same semiconductor material as a semiconductor layer in a semiconductor substrate and at least another pixel containing another charge collection well of a different semiconductor material than the material of the semiconductor layer. The charge collections wells have different band gaps, and consequently, generate charge carriers in response to light having different wavelengths. The CMOS sensor structure thus includes at least two pixels responding to light of different wavelengths, enabling wavelength-sensitive, or color-sensitive, capture of an optical data. | 12-31-2009 |
20100006952 | FIELD EFFECT TRANSISTOR AND METHOD OF FABRICATING SAME - An FET and method of fabricating an FET. The method includes forming a gate dielectric layer on a top surface of a silicon region of a substrate and forming a gate electrode on a top surface of the gate dielectric layer; forming a source and a drain in the silicon region of and separated by a channel region under the gate electrode, the source having a source extension extending under the gate electrode and the drain having a drain extension extending under the gate electrode, the source, source extension, drain and drain extension doped a first type; and forming a source delta region contained entirely within the source and forming a drain delta region contained entirely within the drain, the delta source region and the delta drain region doped a second dopant type, the second dopant type opposite from the first dopant type. | 01-14-2010 |
20100038754 | Back-End-of-Line Resistive Semiconductor Structures - In one embodiment, a back-end-of-line (BEOL) resistive structure comprises a second metal line embedded in a second dielectric layer and overlying a first metal line embedded in a first dielectric layer. A doped semiconductor spacer or plug laterally abutting sidewalls of the second metal line and vertically abutting a top surface of the first metal line provides a resistive link between the first and second metal lines. In another embodiment, another BEOL resistive structure comprises a first metal line and a second metal line are embedded in a dielectric layer. A doped semiconductor spacer or plug laterally abutting the sidewalls of the first and second metal lines provides a resistive link between the first and second metal lines. | 02-18-2010 |
20100041202 | Methods For Forming Back-End-Of-Line Resistive Semiconductor Structures - In one embodiment, a second metal line embedded in a second dielectric layer overlies a first metal line embedded in a first dielectric layer. A portion of the second dielectric layer overlying the first metal line is recessed employing a photoresist and the second metal line as an etch mask. A doped semiconductor spacer is formed within the recess to provide a resistive link between the first metal line and the second metal line. In another embodiment, a first metal line and a second metal line are embedded in a dielectric layer. An area of the dielectric layer laterally abutting the first and second metal lines is recessed employing a photoresist and the first and second metal lines as an etch mask. A doped semiconductor spacer is formed on sidewalls of the first and second metal lines, providing a resistive link between the first and second metal lines. | 02-18-2010 |
20110161896 | BACK-END-OF-LINE RESISTIVE SEMICONDUCTOR STRUCTURES - In one embodiment, a back-end-of-line (BEOL) resistive structure comprises a second metal line embedded in a second dielectric layer and overlying a first metal line embedded in a first dielectric layer. A doped semiconductor spacer or plug laterally abutting sidewalls of the second metal line and vertically abutting a top surface of the first metal line provides a resistive link between the first and second metal lines. In another embodiment, another BEOL resistive structure comprises a first metal line and a second metal line are embedded in a dielectric layer. A doped semiconductor spacer or plug laterally abutting the sidewalls of the first and second metal lines provides a resistive link between the first and second metal lines. | 06-30-2011 |
Patent application number | Description | Published |
20110089499 | STRUCTURE AND METHOD FOR MANUFACTURING ASYMMETRIC DEVICES - A plurality of gate structures are formed on a substrate. Each of the gate structures includes a first gate electrode and source and drain regions. The first gate electrode is removed from each of the gate structures. A first photoresist is applied to block gate structures having source regions in a source-down direction. A first halo implantation is performed in gate structures having source regions in a source-up direction at a first angle. The first photoresist is removed. A second photoresist is applied to block gate structures having source regions in a source-up direction. A second halo implantation is performed in gate structures having source regions in a source-down direction at a second angle. The second photoresist is removed. Replacement gate electrodes are formed in each of the gate structures. | 04-21-2011 |
20110095366 | FORMING AN EXTREMELY THIN SEMICONDUCTOR-ON-INSULATOR (ETSOI) LAYER - Solutions for forming an extremely thin semiconductor-on-insulator (ETSOI) layer are disclosed. In one embodiment, a method includes providing a wafer including a plurality of semiconductor-on-insulator (SOI) layer regions separated by at least one shallow trench isolation (STI); amorphizing the plurality of SOI layer regions by implanting the plurality of SOI layer regions with an implant species; and removing a portion of the amorphized SOI layer region to form at least one recess in the amorphized SOI layer region. | 04-28-2011 |
20110095393 | CREATING EXTREMELY THIN SEMICONDUCTOR-ON-INSULATOR (ETSOI) HAVING SUBSTANTIALLY UNIFORM THICKNESS - An extremely thin semiconductor-on-insulator (ETSOI) wafer is created having a substantially uniform thickness by measuring a semiconductor layer thickness at a plurality of selected points on a wafer; determining a removal thickness to be removed at each of the plurality of selected points such that removal of the removal thickness results in a substantially uniform within-wafer semiconductor layer thickness; implanting a species into the wafer at each of the plurality of selected points with at least one of a dose level and an energy level based on the removal thickness for the respective point; and polishing the semiconductor layer to thin the semiconductor layer. | 04-28-2011 |
20110101506 | Stress Memorization Technique Using Silicon Spacer - A structure for memorizing tensile stress in a semiconductor device includes a gate electrode of the semiconductor device; a silicon spacer adjacent to the gate electrode; and a capping layer encapsulating the gate electrode and the silicon spacer, wherein the silicon spacer and capping layer are configured to cause a tensile stress to be memorized in the gate electrode during an annealing process. A method for memorizing tensile stress in a semiconductor device includes forming a silicon spacer adjacent to a gate electrode of the semiconductor device; forming a capping layer over the silicon spacer and the gate electrode; and annealing the semiconductor device, wherein the silicon spacer and capping layer cause a tensile stress to be memorized in the gate electrode during annealing. A disposable silicon spacer is configured to induce a tensile stress in a semiconductor device during a stress memorization technique process. | 05-05-2011 |
20110254059 | STRUCTURE AND METHOD FOR MANUFACTURING ASYMMETRIC DEVICES - A plurality of gate structures are formed on a substrate. Each of the gate structures includes a first gate electrode and source and drain regions. The first gate electrode is removed from each of the gate structures. A first photoresist is applied to block gate structures having source regions in a source-down direction. A first halo implantation is performed in gate structures having source regions in a source-up direction at a first angle. The first photoresist is removed. A second photoresist is applied to block gate structures having source regions in a source-up direction. A second halo implantation is performed in gate structures having source regions in a source-down direction at a second angle. The second photoresist is removed. Replacement gate electrodes are formed in each of the gate structures. | 10-20-2011 |
20120098087 | FORMING AN EXTREMELY THIN SEMICONDUCTOR-ON-INSULATOR (ETSOI) LAYER - Solutions for forming an extremely thin semiconductor-on-insulator (ETSOI) layer. In one embodiment, a method includes providing a wafer including a plurality of semiconductor-on-insulator (SOI) layer regions separated by at least one shallow trench isolation (STI); amorphizing the plurality of SOI layer regions by implanting the plurality of SOI layer regions with an implant species; and removing a portion of the amorphized SOI layer region to form at least one recess in the amorphized SOI layer region. | 04-26-2012 |
20120217585 | Structure and Method for Manufacturing Asymmetric Devices - A plurality of gate structures are formed on a substrate. Each of the gate structures includes a first gate electrode and source and drain regions. The first gate electrode is removed from each of the gate structures. A first photoresist is applied to block gate structures having source regions in a source-down direction. A first halo implantation is performed in gate structures having source regions in a source-up direction at a first angle. The first photoresist is removed. A second photoresist is applied to block gate structures having source regions in a source-up direction. A second halo implantation is performed in gate structures having source regions in a source-down direction at a second angle. The second photoresist is removed. Replacement gate electrodes are formed in each of the gate structures. | 08-30-2012 |