Patent application number | Description | Published |
20080246117 | SURFACE PATTERNED TOPOGRAPHY FEATURE SUITABLE FOR PLANARIZATION - A method for manufacturing a semiconductor device that comprises implanting a first dopant type in a well region of a substrate to form implanted sub-regions that are separated by non-implanted areas of the well region. The method also comprises forming an oxide layer over the well region, such that an oxide-converted first thickness of the implanted sub-regions is greater than an oxide-converted second thickness of the non-implanted areas. The method further comprises removing the oxide layer to form a topography feature on the well region. The topography feature comprises a surface pattern of higher and lower portions. The higher portions correspond to locations of the non-implanted areas and the lower portions correspond to the implanted sub-regions. | 10-09-2008 |
20090159968 | BVDII Enhancement with a Cascode DMOS - Double diffused MOS (DMOS) transistors feature extended drain regions to provide depletion regions which drop high drain voltages to lower voltages at the gate edges. DMOS transistors exhibit lower drain breakdown potential in the on-state than in the off-state than in the off-state due to snapback by a parasitic bipolar transistor that exists in parallel with the DMOS transistor. The instant invention is a cascoded DMOS transistor in an integrated circuit incorporating an NMOS transistor on the DMOS source node to reverse bias the parasitic emitter-base junction during on-state operation, eliminating snapback. The NMOS transistor may be integrated with the DMOS transistor by connections in the interconnect system of the integrated circuit, or the NMOS transistor and DMOS transistor may be fabricated in a common p-type well and integrated in the IC substrate. Methods of fabricating an integrated circuit with the incentive cascoded DMOS transistor are also disclosed. | 06-25-2009 |
20090166875 | METHODS FOR PREPARING AND DEVICES WITH TREATED DUMMY MOATS - Devices and methods are presented to fabricate dummy moats in an isolation region on a substrate. Presently, dummy moats are prone to losing impedance after the silicidation process. In high-voltage devices, silicided dummy moats reduce the breakdown voltage between active regions, particularly when the dummy moat overlaps or is in close proximity to a junction. The present devices and methods disclose a dummy moat covered with an oxide layer. During the silicidation process, the dummy moat and other designated isolation regions remain non-silicided. Thus, high and stable breakdown voltages are maintained. | 07-02-2009 |
20090256199 | LATERAL METAL OXIDE SEMICONDUCTOR DRAIN EXTENSION DESIGN - A semiconductor device comprising source and drain regions and insulating region and a plate structure. The source and drain regions are on or in a semiconductor substrate. The insulating region is on or in the semiconductor substrate and located between the source and drain regions. The insulating region has a thin layer and a thick layer. The thick layer includes a plurality of insulating stripes that are separated from each other and that extend across a length between the source and the drain regions. The plate structure is located between the source and the drain regions, wherein the plate structure is located on the thin layer and portions of the thick layer, the plate structure having one or more conductive bands that are directly over individual ones of the plurality of insulating stripes. | 10-15-2009 |
20090283827 | Formation Of A MOSFET Using An Angled Implant - A LDMOS transistor having a channel region located between an outer boundary of an n-type region and an inner boundary of a p-body region. A width of the LDMOS channel region is less than 80% of a distance between an outer boundary of an n | 11-19-2009 |
20090286371 | Formation of a MOSFET Using an Angled Implant - A LDMOS transistor having a channel region located between an outer boundary of an n-type region and an inner boundary of a p-body region. A width of the LDMOS channel region is less than 80% of a distance between an outer boundary of an n | 11-19-2009 |
20090294841 | Formation of a MOSFET Using an Angled Implant - A LDMOS transistor having a channel region located between an outer boundary of an n-type region and an inner boundary of a p-body region. A width of the LDMOS channel region is less than 80% of a distance between an outer boundary of an n | 12-03-2009 |
20100032729 | INTEGRATION OF HIGH VOLTAGE JFET IN LINEAR BIPOLAR CMOS PROCESS - A dual channel JFET which can be integrated in an IC without adding process steps is disclosed. Pinch-off voltage is determined by lateral width of a first, vertical, channel near the source contact. Maximum drain voltage is determined by drain to gate separation and length of a second, horizontal, channel under the gate. Pinch-off voltage and maximum drain potential are dependent on lateral dimensions of the drain and gate wells and may be independently optimized. A method of fabricating the dual channel JFET is also disclosed. | 02-11-2010 |
20100148125 | METHOD OF FORMING SEMICONDUCTOR WELLS - A method is provided of forming a semiconductor device. A substrate is provided having a dielectric layer formed thereover. The dielectric layer covers a protected region of the substrate, and has a first opening exposing a first unprotected region of the substrate. A first dopant is implanted into the first unprotected region through the first opening in the dielectric layer, and into the protected region through the dielectric layer. | 06-17-2010 |
20100163998 | TRENCH ISOLATION COMPRISING PROCESS HAVING MULTIPLE GATE DIELECTRIC THICKNESSES AND INTEGRATED CIRCUITS THEREFROM - A method of fabricating an integrated circuit (IC) including a first plurality of MOS transistors having a first gate dielectric having a first thickness in first regions, and a second plurality of MOS transistors having a second gate dielectric having a second thickness in second regions, wherein the first thickness07-01-2010 | |
20100241413 | METHOD AND SYSTEM FOR MODELING AN LDMOS TRANSISTOR - A processor with a computer program product embodied thereon for modeling an LDMOS transistor having a drift region is provided. Characteristic behavior of a CMOS transistor with its body coupled to its source is generated, and characteristic behavior of a resistor is generated, where the resistor is coupled to the drain of the CMOS transistor. Then to account for impact ionization, an impact ionization current for electrons in the drift region an impact ionization current for holes in the drift region are calculated. | 09-23-2010 |
20100252882 | MOS Transistor with Gate Trench Adjacent to Drain Extension Field Insulation - An integrated circuit containing an MOS transistor with a trenched gate abutting an isolation dielectric layer over a drift region. The body well and source diffused region overlap the bottom surface of the gate trench. An integrated circuit containing an MOS transistor with a first trenched gate abutting an isolation dielectric layer over a drift region, and a second trenched gate located over a heavily doped buried layer. The buried layer is the same conductivity type as the drift region. A process of forming an integrated circuit containing an MOS transistor, which includes an isolation dielectric layer over a drift region of a drain of the transistor, and a gate formed in a gate trench which abuts the isolation dielectric layer. The gate trench is formed by removing substrate material adjacent to the isolation dielectric layer. | 10-07-2010 |
20100264486 | FIELD PLATE TRENCH MOSFET TRANSISTOR WITH GRADED DIELECTRIC LINER THICKNESS - An electronic device has a plurality of trenches formed in a semiconducting layer. A vertical drift region is located between and adjacent the trenches. An electrode is located within each trench, the electrode having a gate electrode section and a field plate section. A graded field plate dielectric is located between the field plate section and the vertical drift region. | 10-21-2010 |
20100314670 | STRAINED LDMOS AND DEMOS - An integrated circuit on a (100) substrate containing an n-channel extended drain MOS transistor with drift region current flow oriented in the <100> direction with stressor RESURF trenches in the drift region. The stressor RESURF trenches have stressor elements with more than 100 MPa compressive stress. An integrated circuit on a (100) substrate containing an n-channel extended drain MOS transistor with drift region current flow oriented in the <110> direction with stressor RESURF trenches in the drift region. The stressor RESURF trenches have stressor elements with more than 100 MPa compressive stress. An integrated circuit on a (100) substrate containing a p-channel extended drain MOS transistor with drift region current flow oriented in a <110> direction with stressor RESURF trenches in the drift region. The stressor RESURF trenches have stressor elements with more than 100 MPa tensile stress. | 12-16-2010 |
20110076822 | LATERAL METAL OXIDE SEMICONDUCTOR DRAIN EXTENSION DESIGN - A semiconductor device | 03-31-2011 |
20110108914 | MOS TRANSISTOR WITH GATE TRENCH ADJACENT TO DRAIN EXTENSION FIELD INSULATION - An integrated circuit containing an MOS transistor with a trenched gate abutting an isolation dielectric layer over a drift region. The body well and source diffused region overlap the bottom surface of the gate trench. An integrated circuit containing an MOS transistor with a first trenched gate abutting an isolation dielectric layer over a drift region, and a second trenched gate located over a heavily doped buried layer. The buried layer is the same conductivity type as the drift region. A process of forming an integrated circuit containing an MOS transistor, which includes an isolation dielectric layer over a drift region of a drain of the transistor, and a gate formed in a gate trench which abuts the isolation dielectric layer. The gate trench is formed by removing substrate material adjacent to the isolation dielectric layer. | 05-12-2011 |
20110111569 | MOS TRANSISTOR WITH GATE TRENCH ADJACENT TO DRAIN EXTENSION FIELD INSULATION - An integrated circuit containing an MOS transistor with a trenched gate abutting an isolation dielectric layer over a drift region. The body well and source diffused region overlap the bottom surface of the gate trench. An integrated circuit containing an MOS transistor with a first trenched gate abutting an isolation dielectric layer over a drift region, and a second trenched gate located over a heavily doped buried layer. The buried layer is the same conductivity type as the drift region. A process of forming an integrated circuit containing an MOS transistor, which includes an isolation dielectric layer over a drift region of a drain of the transistor, and a gate formed in a gate trench which abuts the isolation dielectric layer. The gate trench is formed by removing substrate material adjacent to the isolation dielectric layer. | 05-12-2011 |
20110275210 | METHOD OF MAKING VERTICAL TRANSISTOR WITH GRADED FIELD PLATE DIELECTRIC - An electronic device has a plurality of trenches formed in a semiconductor layer. A vertical drift region is located between and adjacent the trenches. An electrode is located within each trench, the electrode having a gate electrode section and a field plate section. A graded field plate dielectric having increased thickness at greater depth is located between the field plate section and the vertical drift region. | 11-10-2011 |
20110309440 | HIGH VOLTAGE TRANSISTOR USING DILUTED DRAIN - An integrated circuit containing an extended drain MOS transistor may be formed by forming a drift region implant mask with mask fingers abutting a channel region and extending to the source/channel active area, but not extending to a drain contact active area. Dopants implanted through the exposed fingers form lateral doping striations in the substrate under the mask fingers. An average doping density of the drift region under the gate is at least 25 percent less than an average doping density of the drift region at the drain contact active area. In one embodiment, the dopants diffuse laterally to form a continuous drift region. In another embodiment, substrate material between lateral doping striations remains an opposite conductivity type from the lateral doping striations. | 12-22-2011 |
20120100679 | THICK GATE OXIDE FOR LDMOS AND DEMOS - A process of forming an integrated circuit, including forming a dummy oxide layer for ion implanting low voltage transistors, replacing the dummy oxide in the low voltage transistor area with a thinner gate dielectric layer, and retaining the dummy oxide for a gate dielectric for a DEMOS or LDMOS transistor. A process of forming an integrated circuit, including forming a dummy oxide layer for ion implanting low voltage and intermediate voltage transistors, replacing the dummy oxide in the low voltage transistors with a thinner gate dielectric layer, replacing the dummy oxide in the intermediate voltage transistor with another gate dielectric layer, and retaining the dummy oxide for a gate dielectric for a DEMOS or LDMOS transistor. | 04-26-2012 |
20120104497 | HIGH VOLTAGE DRAIN EXTENSION ON THIN BURIED OXIDE SOI - An integrated circuit on an SOI substrate containing an extended drain MOS transistor with a through substrate diode in a drain (n-channel) or body region (p-channel) so that the drain or body region is coupled to the handle wafer through a p-n junction. An integrated circuit on an SOI substrate containing an extended drain MOS transistor with a through substrate diode in a drain (n-channel) or body region (p-channel) coupled to the handle wafer through a p-n junction, that is electrically isolated from the drain or body region. A process of forming an integrated circuit on an SOI substrate containing an extended drain MOS transistor with a through substrate diode in a drain (n-channel) or body region (p-channel). | 05-03-2012 |
20120112275 | Drain Extended CMOS with Counter-Doped Drain Extension - An integrated circuit containing a diode with a drift region containing a first dopant type plus scattering centers. An integrated circuit containing a DEMOS transistor with a drift region containing a first dopant type plus scattering centers. A method for designing an integrated circuit containing a DEMOS transistor with a counter doped drift region. | 05-10-2012 |
20120112277 | INTEGRATED LATERAL HIGH VOLTAGE MOSFET - An integrated circuit containing a dual drift layer extended drain MOS transistor with an upper drift layer contacting a lower drift layer along at least 75 percent of a common length of the two drift layers. An average doping density in the lower drift layer is between 2 and 10 times an average doping density in the upper drift layer. A process of forming an integrated circuit containing a dual drift layer extended drain MOS transistor with a lower drift extension under the body region and an isolation link which electrically isolates the body region, using an epitaxial process. A process of forming an integrated circuit containing a dual drift layer extended drain MOS transistor with a lower drift extension under the body region and an isolation link which electrically isolates the body region, on a monolithic substrate. | 05-10-2012 |
20130032863 | INTEGRATED GATE CONTROLLED HIGH VOLTAGE DIVIDER - An integrated circuit containing a gate controlled voltage divider having an upper resistor on field oxide in series with a transistor switch in series with a lower resistor. A resistor drift layer is disposed under the upper resistor, and the transistor switch includes a switch drift layer adjacent to the resistor drift layer, separated by a region which prevents breakdown between the drift layers. The switch drift layer provides an extended drain or collector for the transistor switch. A sense terminal of the voltage divider is coupled to a source or emitter node of the transistor and to the lower resistor. An input terminal is coupled to the upper resistor and the resistor drift layer. A process of forming the integrated circuit containing the gate controlled voltage divider. | 02-07-2013 |
20130032922 | INTEGRATED HIGH VOLTAGE DIVIDER - An integrated circuit containing a voltage divider having an upper resistor of unsilicided gate material over field oxide around a central opening and a drift layer under the upper resistor, an input terminal coupled to an input node of the upper resistor adjacent to the central opening in the field oxide and coupled to the drift layer through the central opening, a sense terminal coupled to a sense node on the upper resistor opposite from the input node, a lower resistor with a sense node coupled to the sense terminal and a reference node, and a reference terminal coupled to the reference node. A process of forming the integrated circuit containing the voltage divider. | 02-07-2013 |
20130062614 | GROUP III-V ENHANCEMENT MODE TRANSISTOR WITH THYRISTOR GATE - An apparatus includes an enhancement mode transistor having multiple Group III-V layers above a substrate and a gate above the Group III-V layers. The gate includes multiple layers of material that form at least a portion of a thyristor. The multiple layers of material may include a first p-type layer of material, an n-type layer of material on the first p-type layer, and a second p-type layer of material on the n-type layer. The multiple layers of material may also include a p-type layer of material, an n-type layer of material on the p-type layer, and a Schottky metal layer on the n-type layer. The enhancement mode transistor may represent a high electron mobility transistor (HEMT) or a heterostructure field effect transistor (HFET). | 03-14-2013 |
20130105909 | HIGH VOLTAGE CMOS WITH TRIPLE GATE OXIDE | 05-02-2013 |
20130157429 | HIGH VOLTAGE TRANSISTOR USING DILUTED DRAIN - An integrated circuit containing an extended drain MOS transistor may be formed by forming a drift region implant mask with mask fingers abutting a channel region and extending to the source/channel active area, but not extending to a drain contact active area. Dopants implanted through the exposed fingers form lateral doping striations in the substrate under the mask fingers. An average doping density of the drift region under the gate is at least 25 percent less than an average doping density of the drift region at the drain contact active area. In one embodiment, the dopants diffuse laterally to form a continuous drift region. In another embodiment, substrate material between lateral doping striations remains an opposite conductivity type from the lateral doping striations. | 06-20-2013 |
20130277739 | Integrated Lateral High Voltage Mosfet - An integrated circuit containing a dual drift layer extended drain MOS transistor with an upper drift layer contacting a lower drift layer along at least 75 percent of a common length of the two drift layers. An average doping density in the lower drift layer is between 2 and 10 times an average doping density in the upper drift layer. A process of forming an integrated circuit containing a dual drift layer extended drain MOS transistor with a lower drift extension under the body region and an isolation link which electrically isolates the body region, using an epitaxial process. A process of forming an integrated circuit containing a dual drift layer extended drain MOS transistor with a lower drift extension under the body region and an isolation link which electrically isolates the body region, on a monolithic substrate. | 10-24-2013 |
20130285137 | PROGRAMMABLE SCR FOR LDMOS ESD PROTECTION - A protection circuit for a DMOS transistor comprises an anode circuit having a first heavily doped region of a first conductivity type ( | 10-31-2013 |
20140001596 | Sinker with a Reduced Width | 01-02-2014 |
20140042452 | III-NITRIDE ENHANCEMENT MODE TRANSISTORS WITH TUNABLE AND HIGH GATE-SOURCE VOLTAGE RATING - A semiconductor device includes an enhancement mode GaN FET with a depletion mode GaN FET electrically coupled in series between a gate node of the enhancement mode GaN FET and a gate terminal of the semiconductor device. A gate node of the depletion mode GaN FET is electrically coupled to a source node of the enhancement mode GaN FET. A source node of said enhancement mode GaN FET is electrically coupled to a source terminal of the semiconductor device, a drain node of the enhancement mode GaN FET is electrically coupled to a drain terminal of said semiconductor device, and a drain node of the depletion mode GaN FET is electrically coupled to a gate terminal of the semiconductor device. | 02-13-2014 |
20140061785 | Drain Extended CMOS with Counter-Doped Drain Extension - An integrated circuit containing a diode with a drift region containing a first dopant type plus scattering centers. An integrated circuit containing a DEMOS transistor with a drift region containing a first dopant type plus scattering centers. A method for designing an integrated circuit containing a DEMOS transistor with a counter doped drift region. | 03-06-2014 |
20140061789 | LATERAL SUPERJUNCTION EXTENDED DRAIN MOS TRANSISTOR - An integrated circuit containing an extended drain MOS transistor with deep semiconductor (SC) RESURF trenches in the drift region, in which each deep SC RESURF trench has a semiconductor RESURF layer at a sidewall of the trench contacting the drift region. The semiconductor RESURF layer has an opposite conductivity type from the drift region. The deep SC RESURF trenches have depth:width ratios of at least 5:1, and do not extend through a bottom surface of the drift region. A process of forming an integrated circuit with deep SC RESURF trenches in the drift region by etching undersized trenches and counterdoping the sidewall region to form the semiconductor RESURF layer. A process of forming an integrated circuit with deep SC RESURF trenches in the drift region by etching trenches and growing an epitaxial layer on the sidewall region to form the semiconductor RESURF layer. | 03-06-2014 |
20140061859 | STACKED ESD CLAMP WITH REDUCED VARIATION IN CLAMP VOLTAGE - An integrated circuit containing a stacked bipolar transistor which includes two bipolar transistors connected in series is disclosed. Each bipolar transistor includes a breakdown inducing feature. The breakdown inducing features have reflection symmetry with respect to each other. A process for forming an integrated circuit containing a stacked bipolar transistor which includes two bipolar transistors connected in series, with breakdown inducing features having reflection symmetry, is also disclosed. | 03-06-2014 |
20140062524 | JFET HAVING WIDTH DEFINED BY TRENCH ISOLATION - A junction field-effect transistor (JFET) includes a substrate having a first-type semiconductor surface including a topside surface, and a top gate of a second-type formed in the semiconductor surface. A first-type drain and a first-type source are formed on opposing sides of the top gate. A first deep trench isolation region has an inner first trench wall and an outer first trench wall surrounding the top gate, the drain and the source, and extends vertically to a deep trench depth from the topside surface. A second-type sinker formed in semiconductor surface extends laterally outside the outer first trench wall. The sinker extends vertically from the topside surface to a second-type deep portion which is both below the deep trench depth and laterally inside the inner first trench wall to provide a bottom gate. | 03-06-2014 |
20140070265 | FAST SWITCHING IGBT WITH EMBEDDED EMITTER SHORTING CONTACTS AND METHOD FOR MAKING SAME - Integrated circuits are presented having high voltage IGBTs with integral emitter shorts and fabrication processes using wafer bonding or gown epitaxial silicon for controlled drift region thickness and fast switching speed. | 03-13-2014 |
20140183631 | LOW COST TRANSISTORS - An integrated circuit containing an analog MOS transistor has an implant mask for a well which blocks well dopants from two diluted regions at edges of the gate, but exposes a channel region to the well dopants. A thermal drive step diffuses the implanted well dopants across the two diluted regions to form a continuous well with lower doping densities in the two diluted regions. Source/drain regions are formed adjacent to and underlapping the gate by implanting source/drain dopants into the substrate adjacent to the gate using the gate as a blocking layer and subsequently annealing the substrate so that the implanted source/drain dopants provide a desired extent of underlap of the source/drain regions under the gate. Drain extension dopants and halo dopants are not implanted into the substrate adjacent to the gate. | 07-03-2014 |
20140183662 | DEEP TRENCH ISOLATION WITH TANK CONTACT GROUNDING - An integrated circuit is formed on a substrate containing a semiconductor material having a first conductivity type. A deep well having a second, opposite, conductivity type is formed in the semiconductor material of the first conductivity type. A deep isolation trench is formed in the substrate through the deep well so as separate an unused portion of the deep well from a functional portion of the deep well. The functional portion of the deep well contains an active circuit element of the integrated circuit. The separated portion of the deep well does not contain an active circuit element. A contact region having the second conductivity type and a higher average doping density than the deep well is formed in the separated portion of the deep well. The contact region is connected to a voltage terminal of the integrated circuit. | 07-03-2014 |
20140252367 | DRIVER FOR NORMALLY ON III-NITRIDE TRANSISTORS TO GET NORMALLY-OFF FUNCTIONALITY - A semiconductor device includes a depletion mode GaN FET and an integrated driver/cascode IC. The integrated driver/cascode IC includes an enhancement mode cascoded NMOS transistor which is connected in series to a source node of the GaN FET. The integrated driver/cascode IC further includes a driver circuit which conditions a gate input signal and provides a suitable digital waveform to a gate node of the cascoded NMOS transistor. The cascoded NMOS transistor and the driver circuit are formed on a same silicon substrate. | 09-11-2014 |
20140252485 | Low-Cost CMOS Structure with Dual Gate Dielectrics and Method of Forming the CMOS Structure - Impurity atoms of a first type are implanted through a gate and a thin gate dielectric into a channel region that has substantially only the first type of impurity atoms at a middle point of the channel region to increase the average dopant concentration of the first type of impurity atoms in the channel region to adjust the threshold voltage of a transistor. | 09-11-2014 |
20140327010 | AVALANCHE ENERGY HANDLING CAPABLE III-NITRIDE TRANSISTORS - A semiconductor device includes a GaN FET with an overvoltage clamping component electrically coupled to a drain node of the GaN FET and coupled in series to a voltage dropping component. The voltage dropping component is electrically coupled to a terminal which provides an off-state bias for the GaN FET. The overvoltage clamping component conducts insignificant current when a voltage at the drain node of the GaN FET is less than the breakdown voltage of the GaN FET and conducts significant current when the voltage rises above a safe voltage limit. The voltage dropping component is configured to provide a voltage drop which increases as current from the overvoltage clamping component increases. The semiconductor device is configured to turn on the GaN FET when the voltage drop across the voltage dropping component reaches a threshold value. | 11-06-2014 |
20140327011 | III-NITRIDE TRANSISTOR LAYOUT - A semiconductor device containing a GaN FET has an isolating gate structure outside the channel area which is operable to block current in the two-dimensional electron gas between two regions of the semiconductor device. The isolating gate structure is formed concurrently with the gate of the GaN FET, and has a same structure as the gate. | 11-06-2014 |
20140329370 | LAYER TRANSFER OF SILICON ONTO III-NITRIDE MATERIAL FOR HETEROGENOUS INTEGRATION - An integrated silicon and III-N semiconductor device may be formed by growing III-N semiconductor material on a first silicon substrate having a first orientation. A second silicon substrate with a second, different, orientation has a release layer between a silicon device film and a carrier wafer. The silicon device film is attached to the III-N semiconductor material while the silicon device film is connected to the carrier wafer through the release layer. The carrier wafer is subsequently removed from the silicon device film. A first plurality of components is formed in and/or on the silicon device film. A second plurality of components is formed in and/or on III-N semiconductor material in the exposed region. In an alternate process, a dielectric interlayer may be disposed between the silicon device film and the III-N semiconductor material in the integrated silicon and III-N semiconductor device. | 11-06-2014 |
20140339671 | METHOD TO FORM STEPPED DIELECTRIC FOR FIELD PLATE FORMATION - A semiconductor device is formed with a stepped field plate over at least three sequential regions in which a total dielectric thickness under the stepped field plate is at least 10 percent thicker in each region compared to the preceding region. The total dielectric thickness in each region is uniform. The stepped field plate is formed over at least two dielectric layers, of which at least all but one dielectric layer is patterned so that at least a portion of a patterned dielectric layer is removed in one or more regions of the stepped field plate. | 11-20-2014 |
20140374766 | BI-DIRECTIONAL GALLIUM NITRIDE SWITCH WITH SELF-MANAGED SUBSTRATE BIAS - A semiconductor device includes a bidirectional GaN FET formed on a non-insulating substrate. The semiconductor device further includes a first electrical clamp connected between the substrate and a first source/drain node of the bidirectional GaN FET, and a second electrical clamp connected between the substrate and a second source/drain node of the bidirectional GaN FET. The first clamp and the second clamp are configured to bias the substrate at a lower voltage level of an applied bias to the first source/drain node and an applied bias to the second source/drain node, within an offset voltage of the relevant clamp. | 12-25-2014 |
20150021614 | CONTROLLED ON AND OFF TIME SCHEME FOR MONOLITHIC CASCODED POWER TRANSISTORS - A semiconductor device includes a depletion mode GaN FET cascoded with an enhancement mode NMOS transistor. A gate of the GaN FET is electrically coupled to a source of the NMOS transistor through a gate network. The gate network controls at least one of a turn-on time and a turn-off time of the GaN FET. The gate network may be controlled by an input signal to a gate of the NMOS transistor. | 01-22-2015 |
20150021687 | SEMICONDUCTOR STRUCTURE AND METHOD OF FORMING THE SEMICONDUCTOR STRUCTURE WITH DEEP TRENCH ISOLATION STRUCTURES - The density of a transistor array is increased by forming one or more deep trench isolation structures in a semiconductor material. The deep trench isolation structures laterally surround the transistors in the array. The deep trench isolation structures limit the lateral diffusion of dopants and the lateral movement of charge carriers. | 01-22-2015 |