An integrated circuit die that may have one vertical transistor and one horizontal transistor is disclosed. The transistors may have substantially different breakdown voltages. The vertical transistor may be used in power circuitry applications and the horizontal transistor may be used in logic circuitry applications.

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 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.

An integrated silicon carbide rectifier circuit with an on chip isolation diode. The isolation diode can be a channel-to-substrate isolation diode or a channel to channel isolation diode.

A method for forming semiconductor devices includes: grinding a backside of a semiconductor wafer with a grinding wheel during a first time interval, wherein the grinding wheel is forward moved during the first time interval, wherein a plurality of semiconductor devices are formed on the semiconductor wafer; polishing the backside of the semiconductor wafer with the grinding wheel in a second time interval, wherein the grinding wheel is backward moved during the second time interval; and dicing the semiconductor wafer to separate the plurality of semiconductor devices from each other without additional polishing of the backside of the semiconductor wafer before dicing the semiconductor wafer.

A semiconductor structure includes fins that have a 2D material, such as Graphene, upon at least the fin sidewalls. The thickness of the 2D material sidewall may be tuned to achieve desired finFET band gap control. Neighboring fins of the semiconductor structure form fin wells. The semiconductor structure may include a fin cap upon each fin and the 2D material is formed upon the sidewalls of the fin and the bottom surface of the fin wells. The semiconductor structure may include a well-plug at the bottom of the fin wells and the 2D material is formed upon the sidewalls and upper surface of the fins. The semiconductor structure may include both fin caps and well-plugs such that the 2D material is formed upon the sidewalls of the fins.

An integrated circuit die that may have one vertical transistor and one horizontal transistor is disclosed. The transistors may have substantially different breakdown voltages. The vertical transistor may be used in power circuitry applications and the horizontal transistor may be used in logic circuitry applications.

A semiconductor layer may be subjected to etching to form a trench therein. An epitaxial layer may be further formed in the trench. Here, the impurity concentration of the epitaxial layer is controlled to be lower than that of the semiconductor layer. In this manner, concentration of electrical fields in the trench is reduced. A first innovations herein provides a semiconductor device including a first semiconductor layer containing impurities of a first conductivity type, a trench provided in the first semiconductor layer on a front surface side thereof, and a second semiconductor layer provided on an inner wall of the trench, where the second semiconductor layer contains impurities of the first conductivity type at a lower concentration than the first semiconductor layer.

A method for manufacturing a semiconductor device having an SiC-IGBT and an SiC-MOSFET in a single semiconductor chip, including forming a second conductive-type SiC base layer on a substrate, and selectively implanting first and second conductive-type impurities into surfaces of the substrate and base layer to form a collector region, a channel region in a surficial portion of the SiC base layer, and an emitter region in a surficial portion of the channel region, the emitter region serving also as a source region of the SiC-MOSFET.

A method of manufacturing a silicon carbide semiconductor power device is provided. In the method, the power device in high voltage (HV) region and CMOS device in the low voltage (LV) region are formed together, so the cost and time can be saved efficiently. First, a first drift layer is formed on a substrate, and then a shielding region is formed in the first drift layer. The shielding region includes a continuous region in the LV region. Then, a second drift layer is formed on the first drift layer. A pick-up region is formed in the second drift layer, wherein the pick-up region connects to the continuous region of the shielding region, and then NMOS and PMOS in the LV region and the power device in HV region are formed simultaneously. NMOS and PMOS are surrounded by the pick-up region and the continuous region, thereby minimizing body effect.

Along dicing lines, cutting grooves that reach a rear surface from a front surface are formed by a first dicing blade in a semiconductor wafer, completely separating the semiconductor wafer into individual semiconductor chips by the cutting grooves. Thereafter, by a second dicing blade that is constituted by abrasive grains having a mean grit size smaller than that of the first dicing blade and that has a blade width wider than that of the first dicing blade, side walls of the cutting grooves, i.e., side surfaces of the semiconductor chips are polished, approaching a specular state.