Aspects of the present disclosure provides a device comprising a P-type semiconductor substrate, an N-type tub above the semiconductor substrate, a P-type region provided in the N-type tub isolated by one or more P-type isolation structures, and an N-type punch-through stopper provided under the P-type regions isolated by the isolation structure(s). The punch-through stopper is heavily doped compared to the N-type tub. The P-type region has a width between the two isolation structures that is equal to or less than that of the N-type punch-through stopper.

A device includes a buried well region and a first HVW region of the first conductivity, and an insulation region over the first HVW region. A drain region of the first conductivity type is disposed on a first side of the insulation region and in a top surface region of the first HVW region. A first well region and a second well region of a second conductivity type opposite the first conductivity type are on the second side of the insulation region. A second HVW region of the first conductivity type is disposed between the first and the second well regions, wherein the second HVW region is connected to the buried well region. A source region of the first conductivity type is in a top surface region of the second HVW region, wherein the source region, the drain region, and the buried well region form a JFET.

A method of forming a double-gated junction field effect transistors (JFET) and a tri-gated metal-oxide-semiconductor field effect transistor (MOSFET) on a common substrate is provided. The double-gated JFET is formed in a first region of a substrate by forming a semiconductor gate electrode contacting sidewall surfaces of a first channel region of a first semiconductor fin and a top surface of a portion of a first fin cap atop the first channel region. The tri-gated MOSFET is formed in a second region of the substrate by forming a metal gate stack contacting a top surface and sidewall surfaces of a second channel region of a second semiconductor fin.

A semiconductor device is provided. The semiconductor device includes a substrate; a well region disposed in the substrate; an isolation structure surrounding an active region in the well region; a source region disposed in the well region; a drain region disposed in the well region; a second conductive type first doped region disposed in the well region and disposed along a periphery of the active region; a second conductive type second doped region disposed in the well region and under the source region, the drain region and the second conductive type first doped region, wherein the second conductive type second doped region is in direct contact with the second conductive type first doped region; a source electrode; a drain electrode and a gate electrode. The present disclosure also provides a method for manufacturing the semiconductor device.

A semiconductor element includes a base substrate that includes a Ga.sub.2O.sub.3-based crystal having a thickness of not less than 0.05 m and not more than 50 m, and an epitaxial layer that includes a Ga.sub.2O.sub.3-based crystal and is epitaxially grown on the base substrate. A semiconductor element includes an epitaxial layer that includes a Ga.sub.2O.sub.3-based crystal including an n-type dopant, an ion implanted layer that is formed on a surface of the epitaxial layer and includes a higher concentration of n-type dopant than the epitaxial layer, an anode electrode connected to the epitaxial layer, and a cathode electrode connected to the ion implanted layer.

A method of forming a double-gated junction field effect transistors (JFET) and a tri-gated metal-oxide-semiconductor field effect transistor (MOSFET) on a common substrate is provided. The double-gated JFET is formed in a first region of a substrate by forming a semiconductor gate electrode contacting sidewall surfaces of a first channel region of a first semiconductor fin and a top surface of a portion of a first fin cap atop the first channel region. The tri-gated MOSFET is formed in a second region of the substrate by forming a metal gate stack contacting a top surface and sidewall surfaces of a second channel region of a second semiconductor fin.

A semiconductor device includes a first conductive type first main electrode region, a first conductive type drift region which makes contact with the first main electrode region, a first conductive type second main electrode region which makes contact with the drift region, a second conductive type well region which is provided in a part of a surface layer portion of the drift region and to which a reference potential is applied, and a first conductive type potential extracting region which is provided in a surface layer portion of the well region and to which the reference potential is applied. The well region serves as a base region which controls a current flowing between the potential extracting region and the drift region. Thus, it is possible to provide a novel semiconductor device which is high in reliability while the increase of the chip size can be suppressed.

A method of triggering avalanche breakdown in a semiconductor device includes providing an electrical coupling and an optical coupling between an auxiliary semiconductor device configured to emit radiation and the semiconductor device including a pn junction between a first layer of a first conductivity type buried below a surface of a semiconductor body and a doped semiconductor region of a second conductivity type disposed between the surface and the first layer. The electrical and optical coupling includes triggering emission of radiation by the auxiliary semiconductor device and triggering avalanche breakdown in the semiconductor device by absorption of the radiation in the semiconductor device.

Manufacturing methods of JFET-type compact three-dimensional memory (3D-M.sub.C) are disclosed. In a memory level stacked above the substrate, an x-line extends from a memory array to an above-substrate decoding stage. A JFET-type transistor is formed on the x-line as a decoding device for the above-substrate decoding stage, where the overlap portion of the x-line with the control-line (c-line) is semi-conductive.

Junction field-effect transistors including inorganic channels and organic gate junctions are used in some applications for forming high resolution active matrix displays. Arrays of such junction field-effect transistors are electrically connected to thin film switching transistors and provide high drive currents for passive devices such as organic light emitting diodes.