Patent application number | Description | Published |
20080242069 | HYBRID SOI/BULK SEMICONDUCTOR TRANSISTORS - Channel depth in a field effect transistor is limited by an intra-layer structure including a discontinuous film or layer formed within a layer or substrate of semiconductor material. Channel depth can thus be controlled much in the manner of SOI or UT-SOI technology but with less expensive substrates and greater flexibility of channel depth control while avoiding floating body effects characteristic of SOI technology. The profile or cross-sectional shape of the discontinuous film may be controlled to an ogee or staircase shape to improve short channel effects and reduce source/drain and extension resistance without increase of capacitance. Materials for the discontinuous film may also be chosen to impose stress on the transistor channel from within the substrate or layer and provide increased levels of such stress to increase carrier mobility. Carrier mobility may be increased in combination with other meritorious effects. | 10-02-2008 |
20090072313 | HARDENED TRANSISTORS IN SOI DEVICES - A series transistor device includes a series source, a series drain, a first constituent transistor, and a second constituent transistor. The first constituent transistor has a first source and a first drain, and the second constituent transistor has a second source and a second drain. All of the constituent transistors have a same conductivity type. The series source is the first source, and the series drain is the second drain. A drain of one of the constituent transistors is merged with a source of another of the constituent transistors. | 03-19-2009 |
20090134925 | APPARATUS AND METHOD FOR HARDENING LATCHES IN SOI CMOS DEVICES - A method of determining one or more transistors within a particular circuit to be respectively replaced with a hardened transistor includes: identifying, as not requiring hardening, one or more transistors; identifying, as candidates for hardening, each transistor in the circuit not previously identified as not requiring hardening; and employing the hardened transistor in place of a transistor identified as a candidate for hardening. The circuit is a latch and the transistor is an SOI CMOS FET. The transistor is also an SOI transistor. The series transistor includes first and second series-connected transistors having a shared source/drain region whereby a drain of the first series-connected transistor is merged with a source of the second series-connected transistor. | 05-28-2009 |
20100237389 | DESIGN STRUCTURE FOR HEAVY ION TOLERANT DEVICE, METHOD OF MANUFACTURING THE SAME AND STRUCTURE THEREOF - The invention relates to a design structure, and more particularly, to a design structure for a heavy ion tolerant device, method of manufacturing the same and a structure thereof. The structure includes a first device having a diffusion comprising a drain region and source region and a second device having a diffusion comprising a drain region and source region. The first and second device are aligned in an end-to-end layout along a width of the diffusion of the first device and the second device. A first isolation region separating the diffusion of the first device and the second device. | 09-23-2010 |
20110037128 | METHOD AND STRUCTURE FOR IMPROVING UNIFORMITY OF PASSIVE DEVICES IN METAL GATE TECHNOLOGY - Method of forming a semiconductor device which includes the steps of obtaining a semiconductor substrate having a logic region and an STI region; sequentially depositing layers of high K material, metal gate, first silicon and hardmask; removing the hardmask and first silicon layers from the logic region; applying a second layer of silicon on the semiconductor substrate such that the logic region has layers of high K material, metal gate and second silicon and the STI region has layers of high K material, metal gate, first silicon, hardmask and second silicon. There may also be a second hardmask layer between the metal gate layer and the first silicon layer in the STI region. There may also be a hardmask layer between the metal gate layer and the first silicon layer in the STI region but no hardmask layer between the first and second layers of silicon in the STI region. | 02-17-2011 |
20110102042 | APPARATUS AND METHOD FOR HARDENING LATCHES IN SOI CMOS DEVICES - A method of determining one or more transistors within a particular circuit to be respectively replaced with a hardened transistor includes: identifying, as not requiring hardening, one or more transistors; identifying, as candidates for hardening, each transistor in the circuit not previously identified as not requiring hardening; and employing the hardened transistor in place of a transistor identified as a candidate for hardening. The circuit is a latch and the transistor is an SOI CMOS FET. The transistor is also an SOI transistor. The series transistor includes first and second series-connected transistors having a shared source/drain region whereby a drain of the first series-connected transistor is merged with a source of the second series-connected transistor. | 05-05-2011 |
20120112246 | DEVICES HAVING REDUCED SUSCEPTIBILITY TO SOFT-ERROR EFFECTS AND METHOD FOR FABRICATION - A semiconductor-on-insulator (SOI) substrate complementary metal oxide semiconductor (CMOS) device and fabrication methods include a p-type field effect transistor (PFET) and an n-type field effect transistor (NFET). Each of the PFET and the NFET include a transistor body of a first type of material and source and drain regions. The source and drain regions have a second type of material such that an injection charge into the source and drain region is greater than a parasitic charge into the transistor body to decrease parasitic bipolar current gain, increase critical charge (Qcrit) and reduce sensitivity to soft errors. | 05-10-2012 |
20120119266 | Stressor in Planar Field Effect Transistor Device - A field effect transistor device includes a gate stack portion disposed on a substrate, and a channel region in the substrate having a depth partially defined by the gate stack portion and a silicon region of the substrate, the silicon region having a sloped profile such that a distal regions of the channel region have greater depth than a medial region of the channel region. | 05-17-2012 |
20120181549 | STRESSED CHANNEL FET WITH SOURCE/DRAIN BUFFERS - A method for forming a stressed channel field effect transistor (FET) with source/drain buffers includes etching cavities in a substrate on either side of a gate stack located on the substrate; depositing source/drain buffer material in the cavities; etching the source/drain buffer material to form vertical source/drain buffers adjacent to a channel region of the FET; and depositing source/drain stressor material in the cavities adjacent to and over the vertical source/drain buffers. | 07-19-2012 |
20120261672 | MINIMIZING LEAKAGE CURRENT AND JUNCTION CAPACITANCE IN CMOS TRANSISTORS BY UTILIZING DIELECTRIC SPACERS - A semiconductor structure and method for forming dielectric spacers and epitaxial layers for a complementary metal-oxide-semiconductor field effect transistor (CMOS transistor) are disclosed. Specifically, the structure and method involves forming dielectric spacers that are disposed in trenches and are adjacent to the silicon substrate, which minimizes leakage current. Furthermore, epitaxial layers are deposited to form source and drain regions, wherein the source region and drain regions are spaced at a distance from each other. The epitaxial layers are disposed adjacent to the dielectric spacers and the transistor body regions (i.e., portion of substrate below the gates), which can minimize transistor junction capacitance. Minimizing transistor junction capacitance can enhance the switching speed of the CMOS transistor. Accordingly, the application of dielectric spacers and epitaxial layers to minimize leakage current and transistor junction capacitance in CMOS transistors can enhance the utility and performance of the CMOS transistors in low power applications. | 10-18-2012 |
20130140636 | STRESSED CHANNEL FET WITH SOURCE/DRAIN BUFFERS - A stressed channel field effect transistor (FET) includes a substrate; a gate stack located on the substrate; a channel region located in the substrate under the gate stack; source/drain stressor material located in cavities in the substrate on either side of the channel region; and vertical source/drain buffers located in the cavities in the substrate between the source/drain stressor material and the substrate, wherein the source/drain stressor material abuts the channel region above the source/drain buffers. | 06-06-2013 |
20130288440 | MINIMIZING LEAKAGE CURRENT AND JUNCTION CAPACITANCE IN CMOS TRANSISTORS BY UTILIZING DIELECTRIC SPACERS - A semiconductor structure and method for forming dielectric spacers and epitaxial layers for a complementary metal-oxide-semiconductor field effect transistor (CMOS transistor) are disclosed. Specifically, the structure and method involves forming dielectric spacers that are disposed in trenches and are adjacent to the silicon substrate, which minimizes leakage current. Furthermore, epitaxial layers are deposited to form source and drain regions, wherein the source region and drain regions are spaced at a distance from each other. The epitaxial layers are disposed adjacent to the dielectric spacers and the transistor body regions (i.e., portion of substrate below the gates), which can minimize transistor junction capacitance. Minimizing transistor junction capacitance can enhance the switching speed of the CMOS transistor. Accordingly, the application of dielectric spacers and epitaxial layers to minimize leakage current and transistor junction capacitance in CMOS transistors can enhance the utility and performance of the CMOS transistors in low power applications. | 10-31-2013 |
20140201699 | METHODS FOR MODELING OF FINFET WIDTH QUANTIZATION - A method for modeling FinFET width quantization is described. The method includes fitting a FinFET model of a FinFET device to single fin current/voltage characteristics. The FinFET device comprises a plurality of fins. The method includes obtaining statistical data of at least one sample FinFET device. The statistical data includes DIBL data and SS data. The method also includes fitting the FinFET model to a variation in a current to turn off the finFETs device (I | 07-17-2014 |
20140201700 | APPARATUS FOR MODELING OF FINFET WIDTH QUANTIZATION - A method for modeling FinFET width quantization is described. The method includes fitting a FinFET model of a FinFET device to single fin current/voltage characteristics. The FinFET device comprises a plurality of fins. The method includes obtaining statistical data of at least one sample FinFET device. The statistical data includes DIBL data and SS data. The method also includes fitting the FinFET model to a variation in a current to turn off the finFETs device (I | 07-17-2014 |
20140264591 | METHOD AND STRUCTURE FOR DIELECTRIC ISOLATION IN A FIN FIELD EFFECT TRANSISTOR - A finFET and method of fabrication are disclosed. A sacrificial layer is formed on a bulk semiconductor substrate. A top semiconductor layer (such as silicon) is disposed on the sacrificial layer. The bulk semiconductor substrate is recessed in the area adjacent to the transistor gate and a stressor layer is formed in the recessed area. The sacrificial layer is selectively removed and replaced with an insulator, such as a flowable oxide. The insulator provides isolation between the transistor channel and the bulk substrate without the use of dopants. | 09-18-2014 |
20140266254 | Techniques for Quantifying Fin-Thickness Variation in FINFET Technology - Techniques for quantifying ΔDfin in FINFET technology are provided. In one aspect, a method for quantifying ΔDfin between a pair of long channel FINFET devices includes the steps of: (a) obtaining Vth values for each of the long channel FINFET devices in the pair; (b) determining a ΔVth for the pair of long channel FINFET devices; and (c) using the ΔVth to determine the ΔDfin between the pair of long channel FINFET devices, wherein the ΔVth is a function of a difference in a Qbody and a gate capacitance between the pair of long channel FINFET devices, and wherein the Qbody is a function of Dfin and Nch for each of the long channel FINFET devices in the pair, and as such the ΔVth is proportional to the ΔDfin between the pair of long channel FINFET devices. | 09-18-2014 |
20140273298 | Techniques for Quantifying Fin-Thickness Variation in FINFET Technology - Techniques for quantifying ΔDfin in FINFET technology are provided. In one aspect, a method for quantifying ΔDfin between a pair of long channel FINFET devices includes the steps of: (a) obtaining Vth values for each of the long channel FINFET devices in the pair; (b) determining a ΔVth for the pair of long channel FINFET devices; and (c) using the ΔVth to determine the ΔDfin between the pair of long channel FINFET devices, wherein the ΔVth is a function of a difference in a Qbody and a gate capacitance between the pair of long channel FINFET devices, and wherein the Qbody is a function of Dfin and Nch for each of the long channel FINFET devices in the pair, and as such the ΔVth is proportional to the ΔDfin between the pair of long channel FINFET devices. | 09-18-2014 |
20140310676 | METHODS FOR MODELING OF FINFET WIDTH QUANTIZATION - A method for modeling FinFET width quantization is described. The method includes fitting a FinFET model of a FinFET device to single fin current/voltage characteristics. The FinFET device comprises a plurality of fins The method includes obtaining statistical data of at least one sample FinFET device. The statistical data includes DIBL data and SS data. The method also includes fitting the FinFET model to a variation in a current to turn off the finFETs device (I | 10-16-2014 |