A semiconductor device includes transistor cells in a semiconductor portion, wherein the transistor cells are electrically connected to a gate metallization, a source electrode and a drain electrode. In one example, the semiconductor device further includes a doped region in the semiconductor portion. The doped region is electrically connected to the source electrode. A resistance of the doped region has a negative temperature coefficient. An interlayer dielectric separates the gate metallization from the doped region. A drain structure in the semiconductor portion electrically connects the transistor cells with the drain electrode and forms a pn junction with the doped region.

A semiconductor device includes a semiconductor layer of a first conductivity type. A well region that is a second conductivity type well region is formed on a surface layer portion of the semiconductor layer and has a channel region defined therein. A source region that is a first conductivity type source region is formed on a surface layer portion of the well region. A gate insulating film is formed on the semiconductor layer and has a multilayer structure. A gate electrode is opposed to the channel region of the well region where a channel is formed through the gate insulating film.

Three-dimensional packaging structure for fan-out of bonding wall of device is provided. A first surface of a device is disposed with bond pads and functional area. The device, except for the first surface, is encapsulated with encapsulation material. A first surface of the encapsulation material horizontally connected to the first surface forms a fan-out surface. A wall structure is disposed on the first surface and extends to the fan-out surface. The wall structure partially covers at least one of the bond pads and comprises first opening corresponding to the at least one of the bond pads. Cover plate is bonded with the wall structure to form cavity corresponding to the functional area and comprises at least one second opening in communication with the first opening. A metal interconnection structure is disposed on surface of the cover plate and is electrically connected to the at least one of the bond pads.

A modular concept for Silicon Carbide power devices is disclosed where a low voltage module (LVM) is designed separately from a high voltage module (HVM). The LVM having a repeating structure in at least a first direction, the repeating structure repeats with a regular distance in at least the first direction, the HVM comprising a buried grid (4) with a repeating structure in at least a second direction, the repeating structure repeats with a regular distance in at least the second direction, along any possible defined direction. Advantages include faster easier design and manufacture at a lower cost.

A modular concept for Silicon Carbide power devices is disclosed where a low voltage module (LVM) is designed separately from a high voltage module (HVM). The LVM having a repeating structure in at least a first direction, the repeating structure repeats with a regular distance in at least the first direction, the HVM comprising a buried grid (4) with a repeating structure in at least a second direction, the repeating structure repeats with a regular distance in at least the second direction, along any possible defined direction. Advantages include faster easier design and manufacture at a lower cost.

A drift structure having a drift zone of a first conductivity type is formed in a SiC semiconductor body of a semiconductor component. Transistor cells each include a doping region and a source region in the SiC semiconductor body. The doping region forms a first pn junction with the drift structure and a second pn junction with the source region. The doping region is electrically connected to a first load electrode. A diode region is formed between the transistor cells and a side surface of the SiC semiconductor body. The diode region is electrically connected to the first load electrode and forms a third pn junction with the drift structure. An emitter efficiency of the diode region is higher than an emitter efficiency of the doping region.

An Enhancement-Mode HEMT having a gate electrode with a doped, Group III-N material disposed between an electrically conductive gate electrode contact and a gate region of the Enhancement-Mode HEMT, such doped, Group III-N layer increasing resistivity of the Group III-N material to deplete the 2DEG under the gate at zero bias.

A cutting method includes: disposing a dicing tape on a back surface of a wafer; holding the wafer on a chuck table through the dicing tape; causing a cutting blade to cut into the wafer held on the chuck table until the tip of the cutting blade reaches the dicing tape to form cut grooves; imaging the cut groove from the front surface side of the wafer by a first imaging section to form a picked-up image of a front surface portion of the cut groove, and imaging the cut groove from the front surface side of the wafer by a second imaging section to form a picked-up image of a back surface portion of the cut groove, thereby checking the picked-up images of the front surface portion and the back surface portion of the cut groove.

A silicon carbide semiconductor power transistor and a method of manufacturing the same. The silicon carbide semiconductor power transistor of the disclosure includes a substrate made of silicon carbide (SiC), a drift layer disposed on the substrate, a gate layer formed on the drift layer, a plurality of first and second well pick-up regions disposed in the drift layer, a plurality of source electrodes, and a plurality of contacts. A plurality of V-grooves is formed in the drift layer. A first opening is formed in the gate layer at a bottom of each of the V-grooves, and a second opening is formed in the gate layer at a top of the drift layer between the V-grooves. The plurality of contacts is disposed inside the second opening to be in direct contact with the second well pick-up regions.

A semiconductor device includes a semiconductor layer of a first conductivity type. A well region that is a second conductivity type well region is formed on a surface layer portion of the semiconductor layer and has a channel region defined therein. A source region that is a first conductivity type source region is formed on a surface layer portion of the well region. A gate insulating film is formed on the semiconductor layer and has a multilayer structure. A gate electrode is opposed to the channel region of the well region where a channel is formed through the gate insulating film.