An apparatus comprises a first conductive structure and at least one transistor in electrical communication with the first conductive structure. The at least one transistor comprises a lower conductive contact coupled to the first conductive structure and a split-body channel on the lower conductive contact. The split-body channel comprises a first semiconductive pillar and a second semiconductive pillar horizontally neighboring the first semiconductive pillar. The at least one transistor also comprises a gate structure horizontally interposed between the first semiconductive pillar and the second semiconductive pillar of the split-body channel and an upper conductive contact vertically overlying the gate structure and coupled to the split-body channel. Portions of the gate structure surround three sides of each of the first semiconductive pillar and the second semiconductive pillar. Memory devices, electronic systems, and methods of forming the apparatus are also disclosed.

A high-electron mobility transistor includes a substrate layer, a first buffer layer provided on the substrate layer, a barrier layer provided on the first buffer layer, a source provided on the barrier layer, a drain provided on the barrier layer, and a gate provided on the barrier layer. The transistor further includes a p-type material layer having a length parallel to a surface of the substrate layer over which the first buffer layer is provided, the length of the p-type material layer being less than an entire length of the substrate layer. The p-type material layer is provided in one of the following: the substrate layer, or the first buffer layer. A process of making the high-electron mobility transistor is disclosed as well.

A method includes forming a metal-oxide-semiconductor field-effect transistor (MOSFET). The Method includes performing an implantation to form a pre-amorphization implantation (PAI) region adjacent to a gate electrode of the MOSFET, forming a strained capping layer over the PAI region, and performing an annealing on the strained capping layer and the PAI region to form a dislocation plane. The dislocation plane is formed as a result of the annealing, with a tilt angle of the dislocation plane being smaller than about 65 degrees.

Provided is a semiconductor device including: a semiconductor substrate having bulk donors distributed throughout the semiconductor substrate; a high-concentration hydrogen peak provided on the semiconductor substrate and having a hydrogen dose amount of 3×10.sup.15/cm.sup.2 or more; a high-concentration region including a position overlapping with the high-concentration hydrogen peak in a depth direction of the semiconductor substrate and having a donor concentration higher than a bulk donor concentration; and a lifetime adjustment portion provided at a position overlapping with the high-concentration hydrogen peak in the depth direction and having a carrier lifetime indicating a minimum value.

Provided is a method of manufacturing an epitaxial wafer, which includes vapor-phase growing an epitaxial layer on a substrate W placed on a susceptor 3 in a state where an upper surface 4b1 of a lift pin 4 inserted in a through-hole H of the susceptor 3 retracts or projects with respect to an upper opening H1a of the through-hole H. A level difference D from the upper surface 4b1 of the lift pin 4 to the opening H1a of the through-hole H is measured with laser light, and outputs, during epitaxial growth, of heaters 9 located above and beneath the susceptor 3 are adjusted on the basis of the measured level difference D. Thus, a method of manufacturing an epitaxial wafer, which facilitates adjustment of the outputs of the heat sources during epitaxial growth, is provided.

A method for growing a single crystal silicon ingot by the continuous Czochralski method is disclosed. The melt depth and thermal conditions are constant during growth because the silicon melt is continuously replenished as it is consumed, and the crucible location is fixed. The critical v/G is determined by the hot zone configuration, and the continuous replenishment of silicon to the melt during growth enables growth of the ingot at a constant pull rate consistent with the critical v/G during growth of a substantial portion of the main body of the ingot. The continuous replenishment of silicon is accompanied by periodic or continuous nitrogen addition to the melt to result in a nitrogen doped ingot.

In a method of manufacturing a semiconductor device, a mask layer and a first layer may be sequentially formed on a substrate. The first layer may be patterned by a photolithography process to form a first pattern. A silicon oxide layer may be formed on the first pattern. A coating pattern including silicon may be formed on the silicon oxide layer. The mask layer may be etched using a second pattern as an etching mask to form a mask pattern, and the second pattern may includes the first pattern, the silicon oxide layer and the coating pattern. The mask pattern may have a uniform size.

Provided is a semiconductor device manufacturing method including a process of annealing a semiconductor wafer in a state in which a supported portion on a lower surface of the semiconductor wafer is supported by using a supporting portion, wherein the supported portion includes one or a plurality of supporting portions and the supporting portion includes one or a plurality of supporting portions, the method comprising: forming impurity regions including a first impurity in a region which is overlapped with the supported portion in a top view and which is apart from an edge of the semiconductor wafer; annealing the semiconductor wafer in a state in which the lower surface of the semiconductor wafer is supported by the supporting portion; and removing the impurity regions by removing a region including the lower surface of the semiconductor wafer.

In a step, acceptor ions are implanted from a back surface of a semiconductor substrate. In a step, a wet process of immersing the semiconductor substrate in a chemical solution including hydrofluoric acid is performed, to introduce hydrogen atoms into the semiconductor substrate. In a step, proton radiation is provided to the back surface of the semiconductor substrate, to introduce hydrogen atoms into the semiconductor substrate and form radiation-induced defects. In a step, an annealing process is performed on the semiconductor substrate, to form hydrogen-related donors by reaction of the hydrogen atoms and the radiation-induced defects and reduce the radiation-induced defects.

In accordance with the present techniques, there is provided a JFET device structures and methods for fabricating the same. Specifically, there is provided a transistor including a semiconductor substrate having a source and a drain. The transistor also includes a doped channel formed in the semiconductor substrate between the source and the drain, the channel configured to pass current between the source and the drain. Additionally, the transistor has a gate comprising a semiconductor material formed over the channel and dielectric spacers on each side of the gate. The source and the drain are spatially separated from the gate so that the gate is not over the drain and source.