An embodiment is a semiconductor device includes a silicon carbide layer having a first plane and a second plane facing the first plane; a gate electrode; an aluminum nitride layer located between the silicon carbide layer and the gate electrode, the aluminum nitride layer containing an aluminum nitride crystal; a first insulating layer located between the silicon carbide layer and the aluminum nitride layer; and a second insulating layer located between the aluminum nitride layer and the gate electrode and having a wider band gap than the aluminum nitride layer.

A semiconductor device of an embodiment includes: a nitride semiconductor layer including a first GaN region of n-type, a second GaN region of n-type on the first GaN region, a third GaN region of p-type on the first GaN region, a fourth GaN region of p-type sandwiching the second GaN region with the third GaN region, a fifth GaN region of p-type on the third GaN region, a sixth GaN region of p-type sandwiching the second GaN region with the fifth GaN region, a seventh GaN region of n-type on the fifth GaN region, an eighth GaN region of n-type on the sixth GaN region, a trench between the seventh GaN region and the eighth GaN region, the trench having an inclination angle of less than 90 degrees; a gate insulating layer including an aluminum nitride film in the trench; a gate electrode; a first electrode; and a second electrode.

The present disclosure provides a semiconductor device and a method of fabricating the same. The device comprises a substrate; a first semiconductor layer formed on the substrate; a second semiconductor layer formed on the first semiconductor layer; the first semiconductor layer having a smaller forbidden band width than the second semiconductor layer; and a first electrode, a second electrode, and a third electrode formed on the second semiconductor layer; the first semiconductor layer corresponding to the third electrode has a strongly P-type doped first region, and the first semiconductor layer corresponding to the second electrode has a weakly P-type doped second region. The present disclosure contributes to achievement of one of the effects of: reducing a gate leakage current, having a high threshold voltage, high power, and high reliability, allowing a low on-resistance and a normally-off state of the device, and providing a stable threshold voltage, so that the semiconductor device has good switching characteristics.

In a general aspect, a silicon carbide (SiC) field-effect transistor (FET) can include a substrate of a first conductivity type, a drift region of the first conductivity type disposed on the substrate, a spreading layer of the first conductivity type disposed in the drift region, a body region of a second conductivity type disposed in the spreading layer, and a source region of the first conductivity type disposed in the body region. The SiC FET can further include a spacer layer of the first conductivity type disposed on the source region the body region and the spreading layer, and a lateral channel region of the first conductivity type disposed in the spacer layer. The SiC FET can also include a gate structure that includes an aluminum nitride layer disposed on the lateral channel region, and an aluminum gallium nitride layer of the second conductivity disposed on the AlN layer.

A monolithic integrated circuit device formed in a multi-layer structure comprises a low-pinch-off-voltage pHEMT and a high-pinch-off-voltage pHEMT. A Schottky layer in the multi-layer structure contains at least three stacked regions of semiconductor material, wherein each of the two adjacent stacked regions differs in material and provides a stacked region contact interface therebetween. The gate-sinking pHEMTs each includes a gate contact, a first gate metal layer, a gate-sinking region, and a gate-sinking bottom boundary. The first gate metal layers are in contact with the topmost stacked region of the Schottky layer. The gate-sinking regions are beneath the first gate metal layers. The gate-sinking bottom boundary of the high-pinch-off-voltage pHEMT, which is closer to the semiconductor substrate than the gate-sinking bottom boundary of the low-pinch-off-voltage pHEMT, locates within 10 Å above or below one of the stacked region contact interfaces of the Schottky layer.

A semiconductor device including: a substrate in which a first transistor region and a second transistor region are provided; a first channel layer in which a carrier of a first conductivity type travels, the first channel layer being provided over the substrate in the first transistor region and including a compound semiconductor; a first impurity epitaxial layer of a second conductivity type that is provided over the substrate with the first channel layer interposed therebetween, is disposed in a first gate region in a central portion and outside the first gate region, and has a low concentration region in which an electric charge amount per unit length is small as compared to the first gate region; and a second channel layer in which a carrier of the second conductivity type travels, the second channel layer being provided over the substrate in the second transistor region and including a compound semiconductor.

Gate fingers extending symmetrically from both sides of gate connecting portions, drain electrodes adjacent to both the gate fingers extending from both the sides of the gate connecting portions, and source electrodes respectively adjacent to the gate fingers extending from both the sides of the gate connecting portions are included. Gate air bridges connect the gate connecting portions and a gate routing line while straddling the source electrodes.

A semiconductor device of an embodiment includes: a nitride semiconductor layer including a first GaN region of n-type, a second GaN region of n-type on the first GaN region, a third GaN region of p-type on the first GaN region, a fourth GaN region of p-type sandwiching the second GaN region with the third GaN region, a fifth GaN region of p-type on the third GaN region, a sixth GaN region of p-type sandwiching the second GaN region with the fifth GaN region, a seventh GaN region of n-type on the fifth GaN region, an eighth GaN region of n-type on the sixth GaN region, a trench between the seventh GaN region and the eighth GaN region, the trench having an inclination angle of less than 90 degrees; a gate insulating layer including an aluminum nitride film in the trench; a gate electrode; a first electrode; and a second electrode.

A method of manufacturing a substrate includes forming a support structure by providing a polycrystalline ceramic core, encapsulating the polycrystalline ceramic core in a first adhesion shell, encapsulating the first adhesion shell in a conductive shell, encapsulating the conductive shell in a second adhesion shell, and encapsulating the second adhesion shell in a barrier shell. The method also includes joining a bonding layer to the support structure, joining a substantially single crystalline silicon layer to the bonding layer, forming an epitaxial silicon layer by epitaxial growth on the substantially single crystalline silicon layer, and forming one or more epitaxial III-V layers by epitaxial growth on the epitaxial silicon layer.

A monolithic integrated circuit device formed in a multi-layer structure comprises a low-pinch-off-voltage pHEMT and a high-pinch-off-voltage pHEMT. A Schottky layer in the multi-layer structure contains at least three stacked regions of semiconductor material, wherein each of the two adjacent stacked regions differs in material and provides a stacked region contact interface therebetween. The gate-sinking pHEMTs each includes a gate contact, a first gate metal layer, a gate-sinking region, and a gate-sinking bottom boundary. The first gate metal layers are in contact with the topmost stacked region of the Schottky layer. The gate-sinking regions are beneath the first gate metal layers. The gate-sinking bottom boundary of the high-pinch-off-voltage pHEMT, which is closer to the semiconductor substrate than the gate-sinking bottom boundary of the low-pinch-off-voltage pHEMT, locates within 10 Å above or below one of the stacked region contact interfaces of the Schottky layer.