A transient voltage suppressor is disclosed that includes an electrode, a substrate disposed on the electrode, the substrate having a first doping, an epitaxial layer disposed on the substrate, the epitaxial layer having a second doping that is different from the first doping, a channel formed in the epitaxial layer having a width W, a length L and a plurality of curved regions, the channel forming a plurality of adjacent sections, the channel having a third doping that is different from the first doping and the second doping and a metal layer formed on top of the channel and contained within the width W of the channel.

A varactor structure includes a substrate. A first and second gate structure are disposed on the substrate. The first and second gate structures each include a base portion and a plurality of line portions connected thereto. The line portions of each of the first and second gate structures is alternately arranged. A meander diffusion region is formed in the substrate and surrounds the line portions. A first set of contact plugs is planned with at least two columns or rows and disposed on the base portions of the first and second gate structures. A second set of contact plugs is planned with at least two columns or rows and disposed on the meander diffusion region. A first conductive layer is disposed on a top end of the first set of contact plugs. A second conductive layer is disposed on a top end of the second set of contact plugs.

A semiconductor structure and a manufacturing method thereof is provided. The semiconductor structure includes a high-resistance silicon substrate and a compound layer located on the high-resistance silicon substrate, by performing a way such as local n-type ion implantation, local n-type ion diffusion, selective region epitaxy growth and the like to the high-resistance silicon substrate, an upper part of the high-resistance silicon substrate is formed into a plurality of local n-type semiconductor regions, p-type semiconductor conductive regions formed in the upper part of the high-resistance silicon substrate due to a diffusion of Al, Ga atoms in the compound layer are eliminated, thereby parasitic capacitance caused by a conductive substrate is greatly reduced, and a resistivity of the high-resistance silicon substrate may be improved under high temperature conditions, and then efficiencies and radio frequency characteristics of a microwave device constituted by the entire semiconductor structure are improved.

The present techniques relate to a semiconductor device having resistance which has a positive temperature coefficient and a suitable value, and to a method for manufacturing a semiconductor device having resistance which has a positive temperature coefficient and a suitable value. The semiconductor device related to the present techniques is a bipolar device in which a current flows through a pn junction. The semiconductor device includes an n-type silicon carbide drift layer, a p-type first silicon carbide layer formed on the silicon carbide drift layer, and a p-type second silicon carbide layer formed on the first silicon carbide layer. Then, the second silicon carbide layer has a positive temperature coefficient of resistance.

A transient voltage suppressor is disclosed that includes an electrode, a substrate disposed on the electrode, the substrate having a first doping, an epitaxial layer disposed on the substrate, the epitaxial layer having a second doping that is different from the first doping, a channel formed in the epitaxial layer having a width W, a length L and a plurality of curved regions, the channel forming a plurality of adjacent sections, the channel having a third doping that is different from the first doping and the second doping and a metal layer formed on top of the channel and contained within the width W of the channel.

The present invention provides a DMOS device and a manufacturing method thereof. The DMOS device includes: a substrate, an epitaxial layer, a high voltage well, a body region, a gate, a source, a drain, a drift buried region and a buried region. A first PN junction is formed between the high voltage well and an upper surface of the substrate. From a cross-section view, along the channel direction, a second PN junction is formed between the drift buried region and the buried region or formed between the high voltage well and the buried region. Along the channel direction, the first PN junction and the second PN junction have respective depths. The depth is defined as a distance extending from the upper face of the epitaxial layer downward along a vertical direction. The depth of the second PN junction is shallower than the depth of the first PN junction.

A semiconductor device having a super junction and a method of manufacturing the semiconductor device capable of obtaining a high breakdown voltage are provided, whereby charge balance of the super junction is further accurately controlled in the semiconductor device that is implemented by an N-type pillar and a P-type pillar. The semiconductor device includes a semiconductor substrate; and a blocking layer including a first conductive type pillar and a second conductive type pillar that extend in a vertical direction on the semiconductor substrate and that are alternately arrayed in a horizontal direction, wherein, in the blocking layer, a density profile of a first conductive type dopant may be uniform in the horizontal direction, and the density profile of the first conductive type dopant may vary in the vertical direction.

Apparatuses and methods are disclosed. One such apparatus includes a well having a first type of conductivity formed within a semiconductor structure having a second type of conductivity. A boundary of the well intersects an active area of a tap to the well.

Embodiments of the present disclosure are directed towards an integrated circuit (IC) die. In embodiments, an IC die may include a semiconductor substrate, a group III-Nitride or II-VI wurtzite layer disposed over the semiconductor substrate, and a plurality of buffer structures at least partially embedded in the group III-Nitride or II-VI wurtzite layer. In some embodiments, each of the plurality of buffer structures may include a central member disposed over the semiconductor substrate, a lower lateral member disposed over the semiconductor substrate and extending laterally away from the central member, and an upper lateral member disposed over the central member and extending laterally from the central member in an opposite direction from the lower lateral member. The plurality of buffer structures may be positioned in a staggered arrangement to terminate defects of the group III-Nitride or II-VI wurtzite layer. Other embodiments may be described and/or claimed.

A gallium nitride power device, including: a gallium nitride substrate; cathodes; a plurality of gallium nitride protruding structures arranged on the gallium nitride substrate and between the cathodes, a groove is formed between adjacent gallium nitride protruding structures; an electron transport layer, covering a top portion and side surfaces of each of the gallium nitride protruding structures; a gallium nitride layer, arranged on the electron transport layer and filling each of the grooves; a plurality of second conductivity type regions, where each of the second conductivity type regions extends downward from a top portion of the gallium nitride layer into one of the grooves, and the top portion of each of the gallium nitride protruding structures is higher than a bottom portion of each of the second conductivity type regions; and an anode, arranged on the gallium nitride layer and the second conductivity type regions.