The present disclosure provides a driving circuit, a driving IC, and a driving system, relating to the technical field of electronic circuits. The driving circuit comprises a control module and a driving signal output module, the control module is electrically connected to the driving signal output module, and the driving signal output module is configured to be electrically connected to a to-be-driven device, wherein the driving signal output module comprises at least two transistors, and the at least two transistors are epitaxially grown on the same substrate; and the control module is configured to control a closed state of the at least two transistors, so as to control an operation state of the to-be-driven device.

A high electron mobility transistor includes a substrate. A first III-V compound layer is disposed on the substrate. A second III-V compound layer is embedded within the first III-V compound layer. A P-type gallium nitride gate is embedded within the second III-V compound layer. A gate electrode is disposed on the second III-V compound layer and contacts the P-type gallium nitride gate. A source electrode is disposed at one side of the gate electrode. A drain electrode is disposed at another side of the gate electrode.

An integrated circuit device including a substrate including a word line trench and a first recess adjacent to a first side wall portion of an inner wall of the word line trench, a channel region on the inner wall and extending in a first direction parallel to an upper surface of the substrate, the channel region including a first channel region in a portion of the substrate adjacent to the inner wall and a second channel region on the inner wall and including a two-dimensional (2D) material of a first conductivity type, a gate insulating layer on the second channel region, a word line on the gate insulating layer and inside the word line trench, and a source region in a first recess and including the 2D material of the first conductivity type may be provided.

A method includes: forming a dielectric fin protruding above a substrate; forming a channel layer over an upper surface of the dielectric fin and along first sidewalls of the dielectric fin, the channel layer including a low dimensional material; forming a gate structure over the channel layer; forming metal source/drain regions on opposing sides of the gate structure; forming a channel enhancement layer over the channel layer; and forming a passivation layer over the gate structure, the metal source/drain regions, and the channel enhancement layer.

A vertical field-effect transistor. The vertical field-effect transistor has: A first semiconductor layer, which has a p-type conductivity, on or over a drift region; a groove structure which penetrates the first semiconductor layer vertically, the groove structure having at least one side wall on which a field-effect transistor (FET)-channel region is formed, the FET-channel region having a III-V-heterostructure for forming a two-dimensional electron gas at an interface of the III-V-heterostructure; a source-drain electrode which is electroconductively connected to the III-V-heterostructure; and a contact structure at least partially on or over the drift region, which forms a Schottky- or hetero-contact at least with the drift region, the contact structure being electroconductively connected to the source-drain electrode, and at least the region lying vertically between the contact structure and the drift region being free of the first semiconductor layer.

The present disclosure provides a semiconductor device and a manufacturing method thereof. The semiconductor device comprises a substrate, a groove formed on the substrate, a channel layer structure grown under restriction of the groove structure, the channel layer structure being exposed from an upper surface of the substrate; a barrier layer covering the exposed channel layer structure, a two-dimensional electron gas and a two-dimensional hole gas respectively formed on a second face and a first face of the channel layer structure, and a source, a gate, and a drain formed on the first face/second face of the channel layer structure, and a bottom electrode formed on the second face/first face of the channel layer structure. The semiconductor device can reduce the gate leakage current, has a high threshold voltage, high power, and high reliability, can achieve a low on-resistance and a normally off state of the device, and can provide a stable threshold voltage, such that the semiconductor device has good switching characteristics. Moreover, the local electric field intensity may be effectively reduced, and the overall performance and reliability of the device may be improved; and the structure and manufacturing process of the semiconductor device are relatively simple, which can effectively reduce the manufacturing cost.

A nitride semiconductor device includes a substrate; a first nitride semiconductor layer above the substrate; a block layer above the first nitride semiconductor layer; a first opening penetrating through the block layer; an electron transit layer and an electron supply layer provided sequentially above the block layer and along an inner surface of the first opening; a gate electrode provided above the electron supply layer to cover the first opening; a second opening penetrating through the electron supply layer and the electron transit layer; a source electrode provided in the second opening; and a drain electrode. When the first main surface is seen in a plan view, (i) the first opening and the source electrode each are elongated in a predetermined direction, and (ii) at least part of an outline of a first end of the first opening in a longitudinal direction follows an arc or an elliptical arc.

A transistor structure is provided, the structure may be for a high electron mobility transistor (HEMT). The HEMT comprises a channel layer arranged over a substrate, the channel layer may have a top surface. A barrier layer may be arranged over the channel layer. A first opening may be in the barrier layer and extend partially into the channel layer. A first barrier liner may be arranged in the first opening and over the channel layer, the first barrier liner may have a bottom surface. The bottom surface of the first barrier liner may be lower than the top surface of the channel layer.

The present disclosure relates to a semiconductor device and a manufacturing method thereof; wherein the semiconductor device comprises a semiconductor device layer including one or more semiconductor devices; a first electrode interconnection layer disposed on a first side of the semiconductor device layer; one or more first metal pillars disposed on the first side of the semiconductor device layer and electrically connected to the first electrode interconnection layer; a first insulating material disposed around the one or more first metal pillars, wherein the first insulating material is an injection molding material; and a second electrode interconnection layer disposed on a second side opposite to the first side of the semiconductor device layer. In the technical scheme of the present disclosure, the temporary substrate is not required to achieve better support strength and complete the related processes of the semiconductor manufacturing process, which is convenient, convenient and low in cost.

A nitride semiconductor device is provided that includes: a substrate; an n-type drift layer above the front surface of the substrate; a p-type base layer above the n-type drift layer; a gate opening in the base layer that reaches the drift layer; an n-type channel forming layer that covers the gate opening and has a channel region; a gate electrode above a section of the channel forming layer in the gate opening; an opening that is separated from the gate electrode and reaches the base layer; an opening formed in a bottom surface of said opening and reaching the drift layer; a source electrode covering the openings; and a drain electrode on the rear surface of the substrate.