A manufacturing method of a junction field effect transistor (JFET) includes: providing a substrate having a first conductivity type, forming a channel region having a second conductive type, forming a field region having the first conductivity type, forming a gate having the first conductivity type, forming a source having the second conductive type, forming a drain having the second conductive type, and forming a lightly doped region having the second conductive type. The channel region is formed by a first ion implantation process step, and the lightly doped region is formed by a second ion implantation process step. The second ion implantation process step implants first conductivity type impurities into a part of the channel region.

A semiconductor device includes a first gallium nitride layer disposed on a semiconductor substrate, and an aluminum gallium nitride layer disposed on the first gallium nitride layer. The semiconductor device also includes an upper recess and a lower recess disposed in the aluminum gallium nitride layer, wherein the upper recess adjoins the lower recess, and the upper recess has a width that is greater than that of the lower recess. The semiconductor device further includes a second gallium nitride layer disposed in the first recess and the second recess, and a gate structure disposed on the second gallium nitride layer. In addition, the semiconductor device includes a source electrode and a drain electrode disposed on the aluminum gallium nitride layer.

In some examples, a transistor comprises a gallium nitride (GaN) layer; a GaN-based alloy layer having a top side and disposed on the GaN layer, wherein source, drain, and gate contact structures are supported by the GaN layer; and a first doped region positioned in a drain access region and extending from the top side into the GaN layer.

A transistor arrangement and a method are disclosed. The transistor arrangement includes: a plurality of first semiconductor regions of a first doping type and a plurality of second semiconductor regions of a second doping type, the first semiconductor regions and the second semiconductor regions being arranged alternatingly in a vertical direction of a semiconductor body; a source region adjoining the plurality of first semiconductor regions; a drain region adjoining the plurality of second semiconductor regions and arranged spaced apart from the source region in a first lateral direction; and a plurality of gate regions each of which adjoins at least one of the plurality of second semiconductor regions and is arranged between the source region and the drain region. At least one of the first and semiconductor regions, but less than each of the first and second semiconductor regions has a doping dose that varies in the first lateral direction.

A vertical JFET is provided. The JFET is mixed with lateral channel structure and p-GaN gate structure. The JFET has a N+ implant source region. In one embodiment, a JFET is provided with a drain metal deposited over a backside of an N substrate, an n-type drift layer epitaxial grown over a topside of the N substrate, a buried P-type block layer deposited over the n-type drift layer, an implanted N+ source region on side walls of the lateral channel layer, and an source metal attached to the top of the p-layer and attached to the implanted N+ source region at the side. In one embodiment, the JFET further comprises a gate layer, and wherein the gate layer is a dielectric gate structure that enables a fully enhanced channel. In another embodiment, the gate layer is a p-type GaN gate structure that enables a partially enhanced channel.

A semiconductor device with a junction type FET includes: a drift layer; a channel layer on the drift layer; a source layer in a surface portion of the channel layer; a gate layer in the channel layer; a body layer in the channel layer; a drain layer disposed on an opposite side of the source layer with respect to the drift layer; a gate wiring electrically connected to the gate layer; a first electrode electrically connected to the source layer and the body layer; and a second electrode electrically connected to the drain layer.

Embodiments of the invention include first and second devices formed on a substrate. The first device includes a bottom source or drain (S/D) region, a plurality of fins formed on portions of the bottom S/D region, a bottom spacer formed on the bottom S/D region, a dielectric layer, a gate, a top S/D region formed on each fin of a plurality of fins, and one or more contacts. The dielectric layer is disposed between the gate and the fin of the plurality of fins. The second device includes a bottom doped region, a channel formed the bottom doped region, a sidewall doped region of the channel, a gate coupled to the sidewall doped region, a top doped region, and one or more contacts. A junction is formed between the channel and the sidewall doped region. The cap layer is formed on the gate and the top doped region.

A semiconductor device is provide. The device includes a first n type of layer, a second n type of layer, and an n+ type of region sequentially disposed on a first surface of a substrate. A trench is disposed on a side surface of the second n type of layer, a p type of region is disposed between the second n type of layer and the trench, and a gate electrode is disposed on a bottom surface of the trench. A source electrode is disposed on the n+ type of region and a drain electrode is disposed on a second surface of the substrate. The second n type of layer includes a first concentration layer, a second concentration layer, a third concentration layer, and a fourth concentration layer sequentially disposed on the first n type of layer.

A vertical JFET is provided. The JFET is mixed with lateral channel structure and p-GaN gate structure. The JFET has a N+ implant source region. In one embodiment, a JFET is provided with a drain metal deposited over a backside of an N substrate, an n-type drift layer epitaxial grown over a topside of the N substrate, a buried P-type block layer deposited over the n-type drift layer, an implanted N+ source region on side walls of the lateral channel layer, and an source metal attached to the top of the p-layer and attached to the implanted N+ source region at the side. In one embodiment, the JFET further comprises a gate layer, and wherein the gate layer is a dielectric gate structure that enables a fully enhanced channel. In another embodiment, the gate layer is a p-type GaN gate structure that enables a partially enhanced channel.

A method of forming an electronic device includes forming first, second and third doped regions at a surface of a semiconductor substrate. A first buried layer is located within the semiconductor substrate below the first, second and third doped regions. Fourth and fifth doped regions are laterally spaced apart along the substrate and extend from the surface of the substrate to the first buried layer, the first, second and third doped regions being located between the fourth and fifth doped regions. A second buried layer is formed within the substrate and between the fourth and fifth doped regions such that a first portion of the semiconductor substrate is located between the first buried layer and the second buried layer, and a second portion of the semiconductor substrate is located between the first, second and third doped regions and the second buried layer.