| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 257280000 | With Schottky gate | 39 |
| 20080197382 | Metal-semiconductor field effect transistors (MESFETs) having self-aligned structures and methods of fabricating the same - Metal-semiconductor field-effect transistors (MESFETS) are provided. A MESFET is provided having a source region, a drain region and a gate. The gate is between the source region and the drain region. A p-type conductivity layer is provided beneath the source region, the p-type conductivity layer being self-aligned to the gate. Related methods of fabricating MESFETs are also provided herein. | 08-21-2008 |
| 20080203446 | COMPOSITE CONTACT FOR SEMICONDUCTOR DEVICE - A composite contact for a semiconductor device is provided. The composite contact includes a DC conducting electrode that is attached to a semiconductor layer in the device, and a capacitive electrode that is partially over the DC conducting electrode and extends beyond the DC conducting electrode. The composite contact provides a combined resistive-capacitive coupling to the semiconductor layer. As a result, a contact impedance is reduced when the corresponding semiconductor device is operated at high frequencies. | 08-28-2008 |
| 20090014758 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - In a semiconductor device, a SiN first protective insulating film is formed on a semiconductor layer. A T-shaped gate electrode is formed on the semiconductor layer. A SiN second protective insulating film spreads in an umbrella shape from above the T-shaped gate electrode. A hollow region is formed between the two SiN films. The SiN films are coated with a SiN third protective insulating film with the hollow region remaining. | 01-15-2009 |
| 20090134435 | METHOD TO REDUCE EXCESS NOISE IN ELECTRONIC DEVICES AND MONOLITHIC INTEGRATED CIRCUITS - This invention proposes the use of a thermodynamic screen placed under the electronic devices whose excess noise is to be reduced in order to block the transverse currents between said devices and subjacent layers that are responsible for the aforementioned excess noise. For epitaxial layers as those used in Microelectronics, the barrier layer ( | 05-28-2009 |
| 20090146191 | LOW LEAKAGE SCHOTTKY CONTACT DEVICES AND METHOD - Method and apparatus are described for semiconductor devices. The method ( | 06-11-2009 |
| 20090173973 | SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME - A semiconductor device has a semiconductor (e.g., a silicon substrate), an electrically conductive region (e.g., a source region and a drain region) which is in contact with the semiconductor to form a Schottky junction, and an insulator. The insulator is in contact with the semiconductor and the electrically conductive region, and has a fixed-charge containing region which contains a fixed charge and extends across a boundary between the semiconductor and the electrically conductive region. | 07-09-2009 |
| 20090315083 | Structure and Method for Forming a Thick Bottom Dielectric (TBD) for Trench-Gate Devices - A semiconductor structure which includes a trench gate FET is formed as follows. A plurality of trenches is formed in a semiconductor region using a mask. The mask includes (i) a first insulating layer over a surface of the semiconductor region, (ii) a first oxidation barrier layer over the first insulating layer, and (iii) a second insulating layer over the first oxidation barrier layer. A thick bottom dielectric (TBD) is formed along the bottom of each trench. The first oxidation barrier layer prevents formation of a dielectric layer along the surface of the semiconductor region during formation of the TBD. | 12-24-2009 |
| 20100032730 | Semiconductor device and method of making the same - A method of making a semiconductor device includes forming a p-type semiconductor region to an n-type semiconductor substrate in such a manner that the p-type semiconductor region is partially exposed to a top surface of the semiconductor substrate, forming a Schottky electrode of a first material in such a manner that the Schottky electrode is in Schottky contact with an n-type semiconductor region exposed to the top surface of the semiconductor substrate, and forming an ohmic electrode of a second material different from the first material in such a manner that the ohmic electrode is in ohmic contact with the exposed p-type semiconductor region. The Schottky electrode is formed earlier than the ohmic electrode. | 02-11-2010 |
| 20100032731 | SCHOTTKY JUNCTION-FIELD-EFFECT-TRANSISTOR (JFET) STRUCTURES AND METHODS OF FORMING JFET STRUCTURES - In accordance with an aspect of the invention, A Schottky junction field effect transistor (JFET) is created using cobalt silicide, or other Schottky material, to form the gate contact of the JFET. The structural concepts can also be applied to a standard JFET that uses N− type or P− type dopants to form the gate of the JFET. In addition, the structures allow for an improved JFET linkup with buried linkup contacts allowing improved noise and reliability performance for both conventional diffusion (N− and P− channel) JFET structures and for Schottky JFET structures. In accordance with another aspect of the invention, the gate poly, as found in a standard CMOS or BiCMOS process flow, is used to perform the linkup between the source and the junction gate and/or between the drain and the junction gate of a junction filed effect transistor (JFET). Use of a bias on the gate linkup of the JFET allows an additional tuning knob for the JFET that can be optimized to trade off breakdown characteristics with reduced on resistance. In accordance with yet another aspect of the invention, a patterned buried layer is used to form the back gate control for a junction field effect transistor (JFET). The structure allows a layout or buried layer pattern change to adjust the pinch-off voltage of the JFET structure. Vertical and lateral diffusion of the buried layer is used to adjust the JFET operating parameters with a simple change in the buried layer patterns. In addition, the structures allow for increased breakdown voltage by leveraging charge sharing concepts and improving channel confinement for power JFET structures. These concepts can also be applied to both N− channel and P− channel diffusion JFETs and to Schottky JFET structures. | 02-11-2010 |
| 20100059798 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD FOR SEMICONDUCTOR DEVICE - There is provided a semiconductor device including: a SiC substrate; an AlGaN layer formed on the SiC substrate; a source electrode and a drain electrode formed on the AlGaN layer so as to be spaced from each other; a first insulation film formed between the source electrode and the drain electrode and having a band-like opening parallel to the drain electrode and the source electrode; a gate electrode formed at the opening in the first insulation film; a second insulation film formed on the first insulation film in such a manner as to cover a surface of the gate electrode; and a source field plate electrode which is formed on the second insulation film and the source electrode and an end portion of which on the drain electrode side is spaced from the second insulation film, thereby suppressing degradation in device performance. | 03-11-2010 |
| 20100123172 | SEMICONDUCTOR DEVICE AND METHOD OF PRODUCING SEMICONDUCTOR DEVICE - A substrate composed of hexagonally crystalline SiC is prepared such that its main surface is in the direction at which the minimum angle between the main surface and a plane perpendicular to the (0001) plane is one degree or less, for example, in the direction at which the minimum angle between the main surface and the [0001] direction, which is perpendicular to the (0001) plane, is one degree or less. A horizontal semiconductor device is formed on one main surface of the substrate prepared by the foregoing method. Thus, it was possible to improve the value of breakdown voltage significantly over the horizontal semiconductor device in which the main surface of the substrate composed of hexagonally crystalline SiC is in the direction along the (0001) direction. | 05-20-2010 |
| 20100140672 | FIELD EFFECT TRANSISTOR - A field effect transistor includes a Schottky layer; a stopper layer formed of InGaP and provided in a recess region on the Schottky layer; a cap layer provided on the stopper layer and formed of GaAs; and a barrier rising suppression region configured to suppress rising of a potential barrier due to interface charge between the stopper layer and the cap layer. The cap layer includes a high concentration cap layer, and a low concentration cap layer provided directly or indirectly under the high concentration cap layer and having an impurity concentration lower than the high concentration cap layer. | 06-10-2010 |
| 20100187577 | SCHOTTKY DIODE - Improved Schottky diodes ( | 07-29-2010 |
| 20100244105 | TRANSISTORS HAVING TEMPERATURE STABLE SCHOTTKY CONTACT METALS - A semiconductor structure having: a semiconductor comprising a indium gallium phosphide and molybdenum metal in Schottky contact with the semiconductor. | 09-30-2010 |
| 20100264467 | TRANSISTOR COMPONENT HAVING A SHIELDING STRUCTURE - A transistor component having a shielding structure. One embodiment provides a source terminal, a drain terminal and control terminal. A source zone of a first conductivity type is connected to the source terminal. A drain zone of the first conductivity type is connected to the drain terminal. A drift zone is arranged between the source zone and the drain zone. A junction control structure is provided for controlling a junction zone in the drift zone between the drain zone and the source zone, at least including one control zone. A shielding structure is arranged in the drift zone between the junction control structure and the drain zone and at least includes a shielding zone of a second conductivity type being complementarily to the first conductivity type. The shielding zone is connected to a terminal for a shielding potential. The at least one control zone and the at least one shielding zone have different geometries or different orientations in a plain that is perpendicular to a current flow direction of the component. | 10-21-2010 |
| 20100301400 | SCHOTTKY DIODE - Improved Schottky diodes ( | 12-02-2010 |
| 20100320508 | HORIZONTALLY DEPLETED METAL SEMICONDUCTOR FIELD EFFECT TRANSISTOR - The present invention provides a horizontally depleted Metal Semiconductor Field Effect Transistor (MESPET). A drain region, a source region, and a channel region are formed in the device layer such that the drain region and the source region are spaced apart from one another and the channel region extends between the drain region and the source region. First and second gate contacts are formed in the device layer on either side of the channel region, and as such, the first and second gate contacts will also reside between opposing portions of the source and drain regions. With this configuration, voltages applied to the first and second gate contacts effectively control vertical depletion regions, which form on either side of the channel region. | 12-23-2010 |
| 20110114999 | SPUTTERING TARGET AND METHOD FOR MANUFACTURING THE SAME, AND TRANSISTOR - To provide a deposition technique for forming an oxide semiconductor film. An oxide semiconductor film is formed using a sputtering target which contains a sintered body of metal oxide and in which the concentration of hydrogen contained in the sintered body of metal oxide is, for example, as low as 1×10 | 05-19-2011 |
| 20110140180 | SEMICONDUCTOR DEVICE HAVING DIODE CHARACTERISTIC - According to one embodiment, a semiconductor device is provided. The semiconductor device has a first region formed of semiconductor and a second region formed of semiconductor which borders the first region. An electrode is formed to be in ohmic-connection with the first region. A third region is formed to sandwich the first region. A first potential difference is produced between the first and the second regions in a thermal equilibrium state, according to a second potential difference between the third region and the first region. | 06-16-2011 |
| 20110215383 | FIELD EFFECT TRANSISTOR AND METHOD FOR FABRICATING THE SAME - A method for fabricating a field effect transistor includes: forming an insulating film provided on a semiconductor layer, the insulating film having an opening via which a surface of the semiconductor layer is exposed and including silicon oxide; forming a Schottky electrode on the insulating film and in the opening, the Schottky electrode having an overhang portion and having a first contact layer that is provided in a region contacting the insulating film and contains oxygen, and a second contact layer that is provided on the first contact layer and contains a smaller content of oxygen than that of the first contact layer; and removing the insulating film by a solution including hydrofluoric acid | 09-08-2011 |
| 20110284931 | transistor device and manufacture method - A transistor device sequentially comprises a semiconductor substrate, a drain, a source, a gate metal seed layer and a gate Schottky contact. The gate metal seed layer comprises a gelatinous substance layer and multiple metal seed crystals. A manufacture method comprises steps of providing a semiconductor substrate; forming a drain and a source; forming a patterned photoresist layer with a photolithography to define a gate area on the semiconductor substrate; forming a gate metal seed layer on the semiconductor substrate with a sensitization process and an activation process; and forming a gate Schottky contact on the gate metal seed layer with an electroless plating approach. | 11-24-2011 |
| 20120007153 | SEMICONDUCTOR DEVICE - A semiconductor device includes: a compound semiconductor substrate; a buffer layer, a channel layer, and a Schottky junction forming layer sequentially disposed on the compound semiconductor substrate, the buffer layer, the channel layer, and the Schottky junction forming layer each being compound semiconductor materials; a source electrode and a drain electrode located on the Schottky junction forming layer; and a gate electrode disposed between the source and drain electrodes and forming a Schottky junction with the Schottky junction forming layer. The dopant impurity concentration in the channel layer is inversely proportional to the third power of depth into the channel layer from a top surface of the channel layer. The gate electrode has a gate length in a range from 0.2 μm to 0.6 μm. | 01-12-2012 |
| 20120025278 | SCHOTTKY DIODE - A Schottky diode comprises an ohmic layer that can serve as a cathode and a metal layer that can serve as an anode, and a drift channel formed of semiconductor material that extends between the ohmic and metal layers. The drift channel includes a heavily doped region adjacent to the ohmic contact layer. The drift channel forms a Schottky barrier with the metal layer. A pinch-off mechanism is provided for pinching off the drift channel while the Schottky diode is reverse-biased. As a result, the level of saturation or leakage current between the metal layer and the ohmic contact layer under a reverse bias condition of the Schottky diode is reduced. | 02-02-2012 |
| 20120025279 | LOW SCHOTTKY BARRIER SEMICONDUCTOR STRUCTURE AND METHOD FOR FORMING THE SAME - A low Schottky barrier semiconductor structure is provided, comprising: a substrate; a SiGe layer with low Ge content formed on the substrate; a channel layer with high Ge content formed on the SiGe layer; a gate stack formed on the substrate and a side wall of one or more layers formed on both sides of the gate stack; a metal source and a metal drain formed in the channel layer and on the both sides of the gate stack respectively; and an insulation layer formed between the substrate and the metal source and between the substrate and the metal drain respectively. | 02-02-2012 |
| 20120080728 | SEMICONDUCTOR DEVICE WITH JUNCTION FIELD-EFFECT TRANSISTOR AND MANUFACTURING METHOD OF THE SAME - A semiconductor device with a JFET is disclosed. The semiconductor device includes a trench and a contact embedded layer formed in the trench. A gate wire is connected to the contact embedded layer, so that the gate wire is connected to an embedded gate layer via the contact embedded layer. In this configuration, it is possible to downsize a contact structure between the embedded gate layer and the gate wire. | 04-05-2012 |
| 20120205726 | Structure And Method For Fabrication Of Field Effect Transistor Gates With Or Without Field Plates - A method for fabrication of a field effect transistor gate, with or without field plates, includes the steps of defining a relatively thin Schottky metal layer by a lithography/metal liftoff or metal deposition/etch process on a semiconductor surface. This is followed by depositing a dielectric passivation layer over the entire wafer and defining a second lithographic pattern coincident with or slightly inset from the boundaries of the previously defined metal gate layer. This is followed by etching the dielectric using dry or wet etching techniques and stripping the resist, followed by exposing and developing a third resist pattern to define the thicker gate metal layers required for electrical conductivity and also for the field plate if one is utilized. The final step is depositing gate and/or field plate metal, resulting in a gate electrode and an integral field plate. | 08-16-2012 |
| 20120256238 | Junction Field Effect Transistor With An Epitaxially Grown Gate Structure - A method of fabricating a semiconductor device that includes forming a replacement gate structure on a portion of a semiconductor substrate, wherein source regions and drain regions are formed in opposing sides of the replacement gate structure. A dielectric is formed on the semiconductor substrate having an upper surface that is coplanar with an upper surface of the replacement gate structure. The replacement gate structure is removed to provide an opening to an exposed portion of the semiconductor substrate. A functional gate conductor is epitaxially grown within the opening in direct contact with the exposed portion of the semiconductor substrate. The method is applicable to planar metal oxide semiconductor field effect transistors (MOSFETs) and fin field effect transistors (finFETs). | 10-11-2012 |
| 20130161706 | JUNCTION FIELD EFFECT TRANSISTOR WITH AN EPITAXIALLY GROWN GATE STRUCTURE - A method of fabricating a semiconductor device that includes forming a replacement gate structure on a portion of a semiconductor substrate, wherein source regions and drain regions are formed in opposing sides of the replacement gate structure. A dielectric is formed on the semiconductor substrate having an upper surface that is coplanar with an upper surface of the replacement gate structure. The replacement gate structure is removed to provide an opening to an exposed portion of the semiconductor substrate. A functional gate conductor is epitaxially grown within the opening in direct contact with the exposed portion of the semiconductor substrate. The method is applicable to planar metal oxide semiconductor field effect transistors (MOSFETs) and fin field effect transistors (finFETs). | 06-27-2013 |
| 20130277718 | JFET DEVICE AND METHOD OF MANUFACTURING THE SAME - A disclosed semiconductor device includes a semiconductor deposition layer formed over an insulation structure and above a substrate. The device includes a gate formed over a contact region between first and second implant regions in the semiconductor deposition layer. The first and second implant regions both have a first conductivity type, and the gate has a second conductivity type. The device may further include a second gate formed beneath the semiconductor deposition layer. | 10-24-2013 |
| 20140145246 | JUNCTION FIELD EFFECT TRANSISTOR WITH AN EPITAXIALLY GROWN GATE STRUCTURE - A method of fabricating a semiconductor device that includes forming a replacement gate structure on a portion of a semiconductor substrate, wherein source regions and drain regions are formed in opposing sides of the replacement gate structure. A dielectric is formed on the semiconductor substrate having an upper surface that is coplanar with an upper surface of the replacement gate structure. The replacement gate structure is removed to provide an opening to an exposed portion of the semiconductor substrate. A functional gate conductor is epitaxially grown within the opening in direct contact with the exposed portion of the semiconductor substrate. The method is applicable to planar metal oxide semiconductor field effect transistors (MOSFETs) and fin field effect transistors (finFETs). | 05-29-2014 |
| 20150311084 | Method for Improving E-Beam Lithography Gate Metal Profile for Enhanced Field Control - A semiconductor device is provided which includes a GaN-on-SiC substrate ( | 10-29-2015 |
| 20150333187 | THIN FILM HYBRID JUNCTION FIELD EFFECT TRANSISTOR - Junction field effect transistors are provided which include a gate junction located on a surface of a crystalline semiconductor material of a first conductivity type. The gate junction can be selected from one of a doped hydrogenated crystalline semiconductor material layer portion of a second conductivity type which is opposite the first conductivity type, a doped hydrogenated non-crystalline semiconductor material layer portion of a second conductivity type which is opposite the first conductivity type, and a Schottky contact. | 11-19-2015 |
| 257281000 | Schottky gate to silicon semiconductor | 4 |
| 20090206375 | Reduced Leakage Current Field-Effect Transistor Having Asymmetric Doping And Fabrication Method Therefor - Reduced leakage current field-effect transistors and fabrication methods. Semiconductor device including substrate of first conductivity type, first well and second well of second conductivity type in substrate, channel of second conductivity type between first well and second well in substrate, and gate region of first conductivity type within channel, wherein gate region is electrically operable to modulate depletion width of channel. First well may be a drain region and the second well may be a source region. Channel includes first link region between gate region and first well or drain region and second link region between the gate region and second well or source region; wherein first link region is of second conductivity type of at least two doping densities. First link region is higher doped in a portion adjacent to drain region than in another portion adjacent to gate region. Method of fabricating a reduced leakage current FET. | 08-20-2009 |
| 20100181603 | METAL SEMICONDUCTOR FIELD EFFECT TRANSISTOR (MESFET) SILICON-ON-INSULATOR STRUCTURE HAVING PARTIAL TRENCH SPACERS - In one embodiment, a metal-semiconductor field effect transistor (MESFET) comprises a first silicon layer, an insulator layer formed on the first silicon layer, and a second silicon layer formed on the insulator layer. A gate region, a source region, and a drain region are formed in the second silicon layer. A first partial trench is formed in the second silicon layer between at least a portion of the gate region and at least a portion of the source region, wherein the first partial trench stops short of the insulator layer. A second partial trench formed in the second silicon layer between at least a portion of the gate region and at least a portion of the drain region, wherein the second partial trench stops short of the insulator layer. First and second oxide spacers are formed in the first and second partial trenches. The first and second oxide spacers and the source region, gate region, and the drain region are substantially planar. | 07-22-2010 |
| 20110024802 | SEMICONDUCTOR DEVICE - To attain reduction in size of a semiconductor device having a power transistor and an SBD, a semiconductor device according to the present invention comprises a first region and a second region formed on a main surface of a semiconductor substrate; plural first conductors and plural second conductors formed in the first and second regions respectively; a first semiconductor region and a second semiconductor region formed between adjacent first conductors in the first region, the second semiconductor region lying in the first semiconductor region and having a conductivity type opposite to that of the first semiconductor region; a third semiconductor region formed between adjacent second conductors in the second region, the third semiconductor region having the same conductivity type as that of the second semiconductor region and being lower in density than the second semiconductor region; a metal formed on the semiconductor substrate in the second region, the third semiconductor region having a metal contact region for contact with the metal, the metal being electrically connected to the second semiconductor region, and a center-to-center distance between adjacent first conductors in the first region being smaller than that between adjacent second conductors in the second region. | 02-03-2011 |
| 20110042727 | MOSFET device with reduced breakdown voltage - A semiconductor device includes a drain, an epitaxial layer overlaying the drain, and an active region. The active region includes a body disposed in the epitaxial layer, a source embedded in the body, a gate trench extending into the epitaxial layer, a gate disposed in the gate trench, a contact trench extending through the source and at least part of the body, a contact electrode disposed in the contact trench, and an epitaxial enhancement portion disposed below the contact trench, wherein the epitaxial enhancement portion has the same carrier type as the epitaxial layer. | 02-24-2011 |
| 257282000 | Gate closely aligned to source region | 1 |
| 257283000 | With groove or overhang for alignment | 1 |
| 20160020301 | METHODS OF MANUFACTURING SEMICONDUCTOR DEVICES - Provided is a method of manufacturing a semiconductor device including: forming a gate electrode structure on an active region of a semiconductor substrate; forming recesses in regions positioned on both sides of the gate electrode structure on the active region; performing a pre-treatment on the recesses using an inert gas plasma; growing epitaxial layers for a source and a drain on the pre-treated recesses; and forming a source electrode structure and a drain electrode structure in the epitaxial layers for the source and the drain, respectively. Also provided is a method in which, after an etching process for forming recesses and/or after an etching process for forming a contact hole, an etched surface may be treated with an inert gas plasma before growing an epitaxial layer. Thus, one or two types of plasma treatment may be employed in the method. | 01-21-2016 |
| 257284000 | Schottky gate in groove | 2 |
| 20100072520 | Methods of Fabricating Transistors Having Buried P-Type Layers Coupled to the Gate - A unit cell of a metal-semiconductor field-effect transistor (MESFET) is provided. The MESFET has a source, a drain and a gate. The gate is between the source and the drain and on an n-type conductivity channel layer. A p-type conductivity region is provided beneath the gate between the source and the drain. The p-type conductivity region is spaced apart from the n-type conductivity channel layer and electrically coupled to the gate. Related methods are also provided herein. | 03-25-2010 |
| 20100163936 | Structure and Method for Fabrication of Field Effect Transistor Gates With or Without Field Plates - A method for fabrication of a field effect transistor gate, with or without field plates, includes the steps of defining a relatively thin Schottky metal layer by a lithography/metal liftoff or metal deposition/etch process on a semiconductor surface. This is followed by depositing a dielectric passivation layer over the entire wafer and defining a second lithographic pattern coincident with or slightly inset from the boundaries of the previously defined metal gate layer. This is followed by etching the dielectric using dry or wet etching techniques and stripping the resist, followed by exposing and developing a third resist pattern to define the thicker gate metal layers required for electrical conductivity and also for the field plate if one is utilized. The final step is depositing gate and/or field plate metal, resulting in a gate electrode and an integral field plate. | 07-01-2010 |
