A complementary metal oxide semiconductor (CMOS)-integrated junction field effect transistor (JFET) has reduced scale and reduced noise. An exemplary JFET has a substrate layer of one dopant type with a gate layer of that dopant type disposed on the substrate, a depletion channel of a second dopant type disposed on the first gate layer, and a second gate layer of the first dopant type disposed on the depletion channel and proximate a surface of the transistor. The second gate layer can separate the depletion channel from the surface, and the depletion channel separates the first gate layer from the second gate layer.

A semiconductor structure includes a semiconductor substrate having a first portion and a second portion. A first Fin field-effect transistor (FinFET) is formed over the first portion of the semiconductor substrate, wherein the first FinFET includes a first fin having a first fin height. A second FinFET is formed over the second portion of the semiconductor substrate, wherein the second FinFET includes a second fin having a second fin height different from the first fin height. A top surface of the first fin is substantially level with a top surface of the second fin. A punch-through stopper is underlying and adjoining the first FinFET, wherein the punch-through stopper isolates the first fin from the first portion of the semiconductor substrate.

A TVS device and a manufacturing method therefor. The TVS device comprises: a first doping type semiconductor substrate (100); a second doping type deep well I (101), a second doping type deep well II (102), and a first doping type deep well (103) provided on the semiconductor substrate; a second doping type heavily doped region I (104) provided in the second doping type deep well I (101); a first doping type well region (105) and a first doping type heavily doped region I (106) provided in the second doping type deep well II (102); a first doping type heavily doped region II (107) and a second doping type heavily doped region II (108) provided in the first doping type deep well (105); a second doping type heavily doped region III (109) located in the first doping type well region (105) and the second doping type deep well II (102); and a first doping type doped region (110) provided in the first doping type well region (105).

A semiconductor device comprises a substrate, a first source/drain region on the substrate, a first channel region extending vertically with respect to the substrate from the first source/drain region, a second source/drain region on the first channel region, a third source/drain region on the second source/drain region, a second channel region extending vertically with respect to the substrate from the third source/drain region, a fourth source/drain region on the second channel region, a first gate region formed around from the first channel region, and a second gate region formed around the second channel region.

A semiconductor device comprises a substrate, a first source/drain region on the substrate, a first channel region extending vertically with respect to the substrate from the first source/drain region, a second source/drain region on the first channel region, a third source/drain region on the second source/drain region, a second channel region extending vertically with respect to the substrate from the third source/drain region, a fourth source/drain region on the second channel region, a first gate region formed around from the first channel region, and a second gate region formed around the second channel region.

Integrated circuit devices may include a plurality of word line structures and a plurality of insulating films that are stacked alternately. Sides of the plurality of word line structures and the plurality of insulating films define a side of a channel hole extending through the plurality of word line structures and the plurality of insulating films. The devices may also include a blocking dielectric film on the side of the channel hole, and a plurality of charge storage films on the blocking dielectric film and on the sides of the plurality of word line structures, respectively. Each of the plurality of charge storage films may include a first charge storage film and a second charge storage film sequentially stacked on a respective one of the sides of the plurality of word line structures. A surface of the second charge storage film may include a recess in a middle portion thereof.

The present disclosure relates to a system and a method for fabricating one or more integrated circuits (ICs). The system includes a plurality of logic tiles formed on a logic wafer and separated by at least one first scribe line, a respective logic tile including a function unit including circuitry configured to perform a respective function; at least one global interconnect configured to communicatively connect the plurality of logic tiles; a plurality of memory tiles formed on a memory wafer connected with the logic wafer, the plurality of memory tiles separated by at least one second scribe line that is substantially aligned with the at least one first scribe line, wherein the logic wafer and the memory wafer are diced along the at least one first scribe line and the at least one second scribe line to obtain a plurality of ICs, a respective IC including at least one logic tile connected with at least one memory tile.

The present disclosure relates to a system and a method for fabricating one or more integrated circuits (ICs). The system includes a plurality of logic tiles formed on a logic wafer and separated by at least one first scribe line, a respective logic tile including a function unit including circuitry configured to perform a respective function; at least one global interconnect configured to communicatively connect the plurality of logic tiles; a plurality of memory tiles formed on a memory wafer connected with the logic wafer, the plurality of memory tiles separated by at least one second scribe line that is substantially aligned with the at least one first scribe line, wherein the logic wafer and the memory wafer are diced along the at least one first scribe line and the at least one second scribe line to obtain a plurality of ICs, a respective IC including at least one logic tile connected with at least one memory tile.

Gallium nitride high-electron-mobility transistors (GaN HEMTs) are at a point of rapid growth in defense (radar, SATCOM) and commercial (5G and beyond) industries. This growth also comes at a point at which the standard GaN heterostructures remain unoptimized for maximum performance. For this reason, the shift to the aluminum nitride (AlN) platform is disclosed. AlN allows for smarter, highly-scaled heterostructure design that improves the output power and thermal management of GaN amplifiers. Beyond improvements over the incumbent amplifier technology, AlN allows for a level of integration previously unachievable with GaN electronics. State-of-the-art high-current p-channel FETs, mature filter technology, and advanced waveguides, all monolithically integrated with an AlN/GaN/AlN HEMT, is made possible with aluminum nitride. It is on this AlN platform that nitride electronics may maximize their full high-power, highspeed potential for mm-wave communication and high-power logic applications.

The present disclosure relates to a system and a method for fabricating one or more integrated circuits (ICs). The system includes a plurality of logic tiles formed on a logic wafer and separated by at least one first scribe line, a respective logic tile including a function unit including circuitry configured to perform a respective function; at least one global interconnect configured to communicatively connect the plurality of logic tiles; a plurality of memory tiles formed on a memory wafer connected with the logic wafer, the plurality of memory tiles separated by at least one second scribe line that is substantially aligned with the at least one first scribe line, wherein the logic wafer and the memory wafer are diced along the at least one first scribe line and the at least one second scribe line to obtain a plurality of ICs, a respective IC including at least one logic tile connected with at least one memory tile.