Class / Patent application number | Description | Number of patent applications / Date published |
257349000 | With means (e.g., a buried channel stop layer) to prevent leakage current along the interface of the semiconductor layer and the insulating substrate | 25 |
20080303089 | INTEGRATED CIRCUIT SYSTEM WITH TRIODE - An integrated circuit system includes an integrated circuit, forming a triode near the integrated circuit, and attaching a connector to the triode and the integrated circuit. | 12-11-2008 |
20090218624 | SOI DEVICE HAVING AN INCREASING CHARGE STORAGE CAPACITY OF TRANSISTOR BODIES AND METHOD FOR MANUFACTURING THE SAME - An SOI device includes an SOI substrate having a stacked structure including a buried oxide layer and a first silicon layer sequentially stacked on a silicon substrate. The SOI substrate possesses grooves having a depth that extends from an upper surface of the first silicon layer to a partial depth of the buried oxide layer. An insulation layer is formed on the lower surfaces of the grooves and a second silicon layer is formed filling the grooves having the insulation layer formed thereon. Gates are formed on the second silicon layer and junction regions are formed in the first silicon layer on both sides of the gates to contact the insulation layer. | 09-03-2009 |
20100090282 | SEMICONDUCTOR INTEGRATED CIRCUIT - The semiconductor integrated circuit has so-called SOI type first MOS transistors (MNtk, MPtk) and second MOS transistors (MNtn, MPtn). The first MOS transistors have a gate isolation film thicker than that the second MOS transistors have. The first and second MOS transistors constitute a power-supply-interruptible circuit ( | 04-15-2010 |
20100140709 | SEMICONDUCTOR DEVICE STRUCTURES INCLUDING TRANSISTORS WITH ENERGY BARRIERS ADJACENT TO TRANSISTOR CHANNELS AND ASSOCIATED METHODS - A semiconductor device structure includes a transistor with an energy barrier beneath its transistor channel. The energy barrier prevents leakage of stored charge from the transistor channel into a bulk substrate. Methods for fabricating semiconductor devices that include energy barriers are also disclosed. | 06-10-2010 |
20100148261 | SEMICONDUCTOR DEVICE AND METHOD FOR PRODUCING THE SAME - A method of the present invention includes a first planarization film formation step of forming, in at least part of a flat portion of the second regions, a first planarization film so as to have a uniform thickness; a second planarization film formation step of forming a second planarization film between the first planarization films to be coplanar with a surface of the first planarization film; a peeling layer formation step of forming a peeling layer by ion implantation of a peeling material into the base layer via the first planarization film or the second planarization film; and a separation step of separating part of the base layer along the peeling layer. | 06-17-2010 |
20110163382 | BODY CONTACTED TRANSISTOR WITH REDUCED PARASITIC CAPACITANCE - A body contacted semiconductor-on-insulator (SOI) metal gate containing transistor that has a reduced parasitic gate capacitance is provided in which a metal portion of a gate stack is removed over the body contact region and a silicon-containing material is formed that contacts the gate dielectric in the body contact region of an SOI substrate. This causes an increase of the effective gate dielectric thickness on the body contact region by greater than 5 angstroms (Å). This results in a lower parasitic capacitance at the body contact region. | 07-07-2011 |
20110221002 | MOS-TYPE ESD PROTECTION DEVICE IN SOI AND MANUFACTURING METHOD THEREOF - The present invention discloses a MOS ESD protection device for SOI technology and a manufacturing method for the device. The MOS ESD protection device comprises: an epitaxial silicon layer grown on top of an SOI substrate; a first side-wall spacer disposed on both sides of the epitaxial silicon layer so as to isolate the ESD protection device from the intrinsic active structures; a source region and a drain region disposed respectively on two sides of the epitaxial silicon layer; a poly silicon gate and a gate dielectric formed on top of the epitaxial silicon layer; and a second side-wall spacer disposed on both sides of the poly silicon gate of . ESD leakage current passes down to the SOI substrate for protection. Because ESD protection device and intrinsic MOS transistor are located in the same plane, this fabrication process can be inserted in the current MOS process flow. | 09-15-2011 |
20130134517 | BORDERLESS CONTACT FOR ULTRA-THIN BODY DEVICES - After formation of a semiconductor device on a semiconductor-on-insulator (SOI) layer, a first dielectric layer is formed over a recessed top surface of a shallow trench isolation structure. A second dielectric layer that can be etched selective to the first dielectric layer is deposited over the first dielectric layer. A contact via hole for a device component located in or on a top semiconductor layer is formed by an etch. During the etch, the second dielectric layer is removed selective to the first dielectric layer, thereby limiting overetch into the first dielectric layer. Due to the etch selectivity, a sufficient amount of the first dielectric layer is present between the bottom of the contact via hole and a bottom semiconductor layer, thus providing electrical isolation for the ETSOI device from the bottom semiconductor layer. | 05-30-2013 |
20130140638 | HIGH DENSITY SIX TRANSISTOR FINFET SRAM CELL LAYOUT - Dual orientation of finFET transistors in a static random access memory (SRAM) cell allows aggressive scaling to a minimum feature size of 15 nm and smaller using currently known masking techniques that provide good manufacturing yield. A preferred layout and embodiment features inverters formed from adjacent, parallel finFETs with a shared gate and different conductivity types developed through a double sidewall image transfer process while the preferred dimensions of the inverter finFETs and the pass transistors allow critical dimensions of all transistors to be sufficiently uniform despite the dual transistor orientation of the SRAM cell layout. | 06-06-2013 |
20140054705 | SILICON GERMANIUM CHANNEL WITH SILICON BUFFER REGIONS FOR FIN FIELD EFFECT TRANSISTOR DEVICE - A fin field effect transistor (finFET) device includes a substrate; first and second source/drain regions located on the substrate; and a fin located on the substrate between the first and second source/drain regions. The fin includes a silicon germanium channel region and first and second silicon buffer regions located in the fin adjacent to and on either side of the silicon germanium channel region. The first silicon buffer region is located between the first source/drain region and the silicon germanium channel region and the second silicon buffer region is located between the second source/drain region and the silicon germanium channel region. | 02-27-2014 |
20140252481 | TRANSISTOR INCLUDING A GATE ELECTRODE EXTENDING ALL AROUND ONE OR MORE CHANNEL REGIONS - A semiconductor structure comprises a substrate and a transistor. The transistor comprises a raised source region and a raised drain region provided above the substrate, one or more elongated semiconductor lines, a gate electrode and a gate insulation layer. The one or more elongated semiconductor lines are connected between the raised source region and the raised drain region, wherein a longitudinal direction of each of the one or more elongated semiconductor lines extends substantially along a horizontal direction that is perpendicular to a thickness direction of the substrate. Each of the elongated semiconductor lines comprises a channel region. The gate electrode extends all around each of the channel regions of the one or more elongated semiconductor lines. The gate insulation layer is provided between each of the one or more elongated semiconductor lines and the gate electrode. | 09-11-2014 |
20140252482 | FINFET TRANSISTOR STRUCTURE AND METHOD FOR MAKING THE SAME - A FINFET transistor structure includes a substrate including a fin structure. Two combined recesses embedded within the substrate, wherein each of the combined recesses includes a first recess extending in a vertical direction and a second recess extending in a lateral direction, the second recess has a protruding side extending to and under the fin structure. Two filling layers respectively fill in the combined recesses. A gate structure crosses the fin structure. | 09-11-2014 |
20150014773 | Partial FIN On Oxide For Improved Electrical Isolation Of Raised Active Regions - A semiconductor fin suspended above a top surface of a semiconductor layer and supported by a gate structure is formed. An insulator layer is formed between the top surface of the semiconductor layer and the gate structure. A gate spacer is formed, and physically exposed portions of the semiconductor fin are removed by an anisotropic etch. Subsequently, physically exposed portions of the insulator layer can be etched with a taper. Alternately, a disposable spacer can be formed prior to an anisotropic etch of the insulator layer. The lateral distance between two openings in the dielectric layer across the gate structure is greater than the lateral distance between outer sidewalls of the gate spacers. Selective deposition of a semiconductor material can be performed to form raised active regions. | 01-15-2015 |
20150021691 | FINFET WITH ELECTRICALLY ISOLATED ACTIVE REGION ON BULK SEMICONDUCTOR SUBSTRATE AND METHOD OF FABRICATING SAME - A semiconductor stack of a FinFET in fabrication includes a bulk silicon substrate, a selectively oxidizable sacrificial layer over the bulk substrate and an active silicon layer over the sacrificial layer. Fins are etched out of the stack of active layer, sacrificial layer and bulk silicon. A conformal oxide deposition is made to encapsulate the fins, for example, using a HARP deposition. Relying on the sacrificial layer having a comparatively much higher oxidation rate than the active layer or substrate, selective oxidization of the sacrificial layer is performed, for example, by annealing. The presence of the conformal oxide provides structural stability to the fins, and prevents fin tilting, during oxidation. Selective oxidation of the sacrificial layer provides electrical isolation of the top active silicon layer from the bulk silicon portion of the fin, resulting in an SOI-like structure. Further fabrication may then proceed to convert the active layer to the source, drain and channel of the FinFET. The oxidized sacrificial layer under the active channel prevents punch-through leakage in the final FinFET structure. | 01-22-2015 |
20150129966 | TRANSISTOR INCLUDING A GATE ELECTRODE EXTENDING ALL AROUND ONE OR MORE CHANNEL REGIONS - A semiconductor structure comprises a substrate and a transistor. The transistor comprises a raised source region and a raised drain region provided above the substrate, one or more elongated semiconductor lines, a gate electrode and a gate insulation layer. The one or more elongated semiconductor lines are connected between the raised source region and the raised drain region, wherein a longitudinal direction of each of the one or more elongated semiconductor lines extends substantially along a horizontal direction that is perpendicular to a thickness direction of the substrate. Each of the elongated semiconductor lines comprises a channel region. The gate electrode extends all around each of the channel regions of the one or more elongated semiconductor lines. The gate insulation layer is provided between each of the one or more elongated semiconductor lines and the gate electrode. | 05-14-2015 |
20150145046 | SEMICONDUCTOR STRUCTURE AND METHOD FOR MANUFACTURING THE SAME - The present invention provides a method for manufacturing a semiconductor structure, which comprises following steps: providing a substrate, which comprises upwards in order a base layer, a buried isolation layer, a buried ground layer, an ultra-thin insulating buried layer and a surface active layer; implementing ion implantation doping to the buried ground layer; forming a gate stack, sidewall spacers and source/drain regions on the substrate; forming a mask layer on the substrate that covers the gate stack and the source/drain regions, and etching the mask layer to expose the source region; etching the source region and the ultra-thin insulating buried layer under the source region to form an opening that exposes the buried ground layer; filling the opening through epitaxial process to form a contact plug for the buried ground layer. Accordingly, the present invention further provides a semiconductor structure. The present invention proposes formation of a buried ground layer contact plug, which thence connects buried ground layer electrically to source region, thereby enhancing control capabilities of a semiconductor device over threshold voltages, suppressing short-channel effects and improving device performance; whereas no independent contact is required to build for the buried ground layer, which thence saves device area and simplifies manufacturing process accordingly. | 05-28-2015 |
20150318377 | FINFET WITH EPITAXIAL SOURCE AND DRAIN REGIONS AND DIELECTRIC ISOLATED CHANNEL REGION - A semiconductor device is provided that includes a pedestal of an insulating material present over at least one layer of a semiconductor material, and at least one fin structure in contact with the pedestal of the insulating material. Source and drain region structures are present on opposing sides of the at least one fin structure. At least one of the source and drain region structures includes at least two epitaxial material layers. A first epitaxial material layer is in contact with the at least one layer of semiconductor material. A second epitaxial material layer is in contact with the at least one fin structure. The first epitaxial material layer is separated from the at least one fin structure by the second epitaxial material layer. A gate structure present on the at least one fin structure. | 11-05-2015 |
20160013287 | SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME | 01-14-2016 |
20160035820 | UNIAXIALLY-STRAINED FD-SOI FINFET - Methods and structures for forming uniaxially-strained, nanoscale, semiconductor bars from a biaxially-strained semiconductor layer are described. A spatially-doubled mandrel process may be used to form a mask for patterning dense, narrow trenches through the biaxially-strained semiconductor layer. The resulting slicing of the biaxially-strained layer enhances carrier mobility and can increase device performance. | 02-04-2016 |
20160093739 | FINFET SEMICONDUCTOR DEVICE WITH ISOLATED CHANNEL REGIONS - A FinFET device includes a fin structure positioned in the channel region of the device and a gate structure positioned above the fin structure, wherein the fin structure includes a portion of a semiconductor substrate and an epi semiconductor material positioned vertically above the portion of the semiconductor substrate. Sidewall spacers are positioned adjacent the gate structure and a fin cavity is positioned in source/drain regions of the device, wherein the fin structure has edges in a gate width direction that are substantially self-aligned with the sidewall spacers and the semiconductor substrate defines the bottom of the fin cavity. A silicon etch stop layer is positioned on and in contact with the edges of the fin structure and within the fin cavity, and a stressed semiconductor material is positioned on and in contact with the silicon etch stop layer and at least partially within the fin cavity. | 03-31-2016 |
20160111492 | Semiconductor Film with Adhesion Layer and Method for Forming the Same - Presented herein is a device including an insulator layer disposed over a substrate. An adhesion layer is disposed over the insulator layer and includes a semiconductor oxide, the semiconductor oxide including a compound of a semiconductor element and oxygen. A semiconductor film layer is over the adhesion layer, the semiconductor film layer being a material including the semiconductor element, the semiconductor film layer having a different composition than the adhesion layer. Bonds at an interface between the insulator layer and the adhesion layer comprise oxygen-hydrogen bonds and oxygen-semiconductor element bonds. | 04-21-2016 |
20160133703 | FinFETs Having Dielectric Punch-Through Stoppers - A semiconductor structure includes a semiconductor substrate; a planar transistor on a first portion of the semiconductor substrate, wherein the first portion of the semiconductor substrate has a first top surface; and a multiple-gate transistor on a second portion of the semiconductor substrate. The second portion of the semiconductor substrate is recessed from the first top surface to form a fin of the multiple-gate transistor. The fin is electrically isolated from the semiconductor substrate by an insulator. | 05-12-2016 |
20160141427 | Multi-Channel Field Effect Transistors Using 2D-Material - A device includes a semiconductor substrate, a buried oxide over the substrate, a first transition metal dichalcogenide layer over the buried oxide, an insulator over the first transition metal dichalcogenide layer, and a second transition metal dichalcogenide layer over the insulator. A gate dielectric is over the second transition metal dichalcogenide layer, and a gate is over the gate dielectric. | 05-19-2016 |
20160181097 | Epitaxial Growth Techniques for Reducing Nanowire Dimension and Pitch | 06-23-2016 |
20160379978 | SEMICONDUCTOR DEVICE AND FABRICATING THE SAME - The present disclosure provides a method for fabricating an integrated circuit device. The method includes providing a precursor including a substrate having first and second metal-oxide-semiconductor (MOS) regions. The first and second MOS regions include first and second gate regions, semiconductor layer stacks, and source/drain regions respectively. The method further includes laterally exposing and oxidizing the semiconductor layer stack in the first gate region to form first outer oxide layer and inner nanowire set, and exposing the first inner nanowire set. A first high-k/metal gate (HK/MG) stack wraps around the first inner nanowire set. The method further includes laterally exposing and oxidizing the semiconductor layer stack in the second gate region to form second outer oxide layer and inner nanowire set, and exposing the second inner nanowire set. A second HK/MG stack wraps around the second inner nanowire set. | 12-29-2016 |