An integrated circuit is formed by providing a heavily doped substrate of a first conductivity type, forming a lightly doped lower epitaxial layer of the first conductivity type over the substrate, implanting dopants of the first conductivity type into the lower epitaxial layer in an area for a shallow component and blocking the dopants from an area for a deep component, forming a lightly doped upper epitaxial layer over the lower epitaxial layer and activating the implanted dopants to form a heavily doped region. The shallow component is formed over the heavily doped region, and the deep component is formed outside the heavily doped region, extending through the upper epitaxial layer into the lower epitaxial layer.

A method for producing a semiconductor device in accordance with various embodiments may include providing a semiconductor workpiece attached to a first carrier; dicing the semiconductor workpiece and the carrier so as to form at least one individual semiconductor chip; mounting the at least one semiconductor chip with a side facing away from the carrier, to an additional carrier.

A semiconductor device is disclosed. The semiconductor device includes a substrate and a plurality of devices on the substrate, wherein a first device of the devices includes a first nitride semiconductor layer on the substrate, a second nitride semiconductor layer brought together with the first nitride semiconductor layer to form a first heterojunction interface, between the substrate and the first nitride semiconductor layer, a third nitride semiconductor layer brought together with the second nitride semiconductor layer to form a second heterojunction interface, between the substrate and the second nitride semiconductor layer, and a first contact electrically connected to the first and second heterojunction interfaces.

A semiconductor device includes a first drain region that is made primarily of SiC, a drift layer, a channel region, a first source region, a source electrode that is formed on the first source region, a second drain region that is connected to the first source region, a second source region that is formed separated from the second drain region, a first floating electrode that is connected to the second source region and to the channel region, first gate electrodes, and a second gate electrode that is connected to the first gate electrodes.

The present disclosure provides a method that includes providing a semiconductor structure having a bottom channel region and a top channel region over the bottom channel region; forming a gate dielectric layer over and wrapping around top channels in the top channel region; performing a radical treatment on the dielectric layer in a supercritical fluid; and forming a metal gate electrode on the dielectric layer.

Disclosed herein are related to a device including vertically placed semiconductor devices in a trench, and a method of fabricating the vertically placed semiconductor devices. In one aspect, a device includes a substrate including a trench defined by a first sidewall and a second sidewall facing each other along a first direction, and a floor between one end of the first sidewall and one end of the second sidewall. The device may include two or more vertical slots separated by vertical nano sheets extending upwards from the floor within the trench. In one aspect, the semiconductor devices can be formed in the two or more vertical slots. For example, source/drain structures, gate structures, and additional source/drain structures of vertical transistors can be formed in the two or more vertical slots.

The present disclosure provides a semiconductor structure and a manufacturing method thereof. The manufacturing method includes: depositing a thin-film stacked structure on a substrate; forming a first hole in the thin-film stacked structure; growing an epitaxial silicon pillar in the first hole; etching the thin-film stacked structure and the epitaxial silicon pillar along a first direction to form a first trench, the first trench passing through a center of the epitaxial silicon pillar and dividing the epitaxial silicon pillar into a first half pillar and a second half pillar; forming a first isolation layer; forming a first channel region of a first doping type, and forming a second channel region of a second doping type; and forming a gate dielectric layer and a gate conductive layer on a surface of each of the first channel region and the second channel region.

The present disclosure provides a nitride-based bidirectional switching device with substrate potential management capability. The device has a control node, a first power/load node, a second power/load node and a main substrate, and comprises: a nitride-based bilateral transistor and a substrate potential management circuit configured for managing a potential of the main substrate. By implementing the substrate potential management circuit, the substrate potential can be stabilized to a lower one of the potentials of the first source/drain and the second source/drain of the bilateral transistor no matter in which directions the bidirectional switching device is operated. Therefore, the bilateral transistor can be operated with a stable substrate potential for conducting current in both directions.

The present disclosure provides a nitride-based bidirectional switching device with substrate potential management capability. The device has a control node, a first power/load node, a second power/load node and a main substrate, and comprises: a nitride-based bilateral transistor and a substrate potential management circuit configured for managing a potential of the main substrate. By implementing the substrate potential management circuit, the substrate potential can be stabilized to a lower one of the potentials of the first source/drain and the second source/drain of the bilateral transistor no matter in which directions the bidirectional switching device is operated. Therefore, the bilateral transistor can be operated with a stable substrate potential for conducting current in both directions.

A semiconductor device and methods of fabricating the same are disclosed. The semiconductor device includes a substrate, a fin structure with a fin top surface disposed on the substrate, a source/drain (S/D) region disposed on the fin structure, a gate structure disposed on the fin top surface, and a gate spacer with first and second spacer portions disposed between the gate structure and the S/D region. The first spacer portion extends above the fin top surface and is disposed along a sidewall of the gate structure. The second spacer portion extends below the fin top surface and is disposed along a sidewall of the S/D region.