A semiconductor device includes a semiconductor layer having first and second surfaces, a first electrode and a first gate electrode along the first surface, and a second electrode and a second gate electrode along the second surface. The layer includes a first type first region, a second type second region between the first region and the first surface and facing the first gate electrode, a first type third region between the second region and the first surface and contacting the first electrode, a second type fourth region between the first region and the second surface, facing the second gate electrode, and contacting the second electrode, and a first type fifth region between the fourth region and the second surface and contacting the second electrode. Transistors including the first and second gate electrodes have different threshold voltages that are both positive or negative.

The method of manufacturing an integrated circuit includes obtaining a silicon carbide substrate of a first conductivity type having an epitaxial layer of a second conductivity type thereon. A dopant is implanted in the epitaxial layer to form a first region of the first conductivity type that extends the full depth of the epitaxial layer. A first transistor is formed in the first region and a second transistor is formed in the epitaxial layer.

The method of manufacturing an integrated circuit includes obtaining a silicon carbide substrate of a first conductivity type having an epitaxial layer of a second conductivity type thereon. A dopant is implanted in the epitaxial layer to form a first region of the first conductivity type that extends the full depth of the epitaxial layer. A first transistor is formed in the first region and a second transistor is formed in the epitaxial layer.

Semiconductor structures and the manufacturing method thereof are disclosed. An exemplary semiconductor structure according to the present disclosure includes a substrate having a p-type well or an n-type well, a first base portion over the p-type well, a second base portion over the n-type well, a first plurality of channel members over the first base portion, a second plurality of channel members over the second base portion, an isolation feature disposed between the first base portion and the second base portion, and a deep isolation structure in the substrate disposed below the isolation feature.

A power inverter includes a bridge circuit including a first half-bridge and a second half-bridge, each half-bridge including a high-side device and a low-side device, and a gate driver circuit connected with each gate of the high-side device and low-side power device of the first and second half-bridges and operable to provide each gate with a respective voltage to control operation of the respective power device. The gate driver is operable to provide a first voltage which is higher than a first threshold voltage of the respective power device, and a second voltage which is higher than a surge threshold of the respective power device. The surge threshold is higher than the first threshold and defines the onset of a surge current operation area of the respective power device at which the power device becomes conducts a surge current that is larger than the rated current of the device.

An SCR with a first semiconductor region and plural concentric semiconductor regions, each surrounding the first semiconductor region. The SCR also includes, surrounded by at least one concentric semiconductor region in the plurality of concentric semiconductor regions, an electrically non-contacted region of a semiconductor type and positioned to modulate a snapback voltage of the silicon controlled rectifier and an electrically-contacted region of the semiconductor type and positioned to provide a diodic response between the at least one concentric semiconductor region in the plurality of concentric semiconductor regions and the electrically-contacted region.

An SCR with a first semiconductor region and plural concentric semiconductor regions, each surrounding the first semiconductor region. The SCR also includes, surrounded by at least one concentric semiconductor region in the plurality of concentric semiconductor regions, an electrically non-contacted region of a semiconductor type and positioned to modulate a snapback voltage of the silicon controlled rectifier and an electrically-contacted region of the semiconductor type and positioned to provide a diodic response between the at least one concentric semiconductor region in the plurality of concentric semiconductor regions and the electrically-contacted region.

A non-uniform base width bipolar junction transistor (BJT) device includes: a semiconductor substrate, the semiconductor substrate having an upper surface; and a BJT device, the BJT device comprising a collector region, a base region, and an emitter region positioned in the semiconductor substrate, the base region being positioned between the collector region and the emitter region; the base region comprising a top surface and a bottom surface, wherein a first width of the top surface of the base region in a base width direction of the BJT device is greater than a second width of the bottom surface of the base region in the base width direction of the BJT device.

A bandgap voltage reference circuit includes first and second transistors (e.g., 3-terminal BJTs or diode-connected BJTs), and a PTAT element (e.g., resistance or capacitance). The first transistor is at a first die location, and operates with a first base-emitter voltage. The second transistor is at a second die location, and operates with a second base-emitter voltage. Each of the first and second transistors may include multiple individual parallel-connected transistors. The PTAT element is operatively coupled to the first and second transistors such that a voltage difference between the first and second base-emitter voltages drops across the PTAT element. The first and second locations are separated by a distance (e.g., 1.5% or more of die length, or such that the respective centroids of the first and second transistor are spaced from one another). Such spatial distribution helps mitigate voltage shift induced by mechanical stress, and is insensitive to process variation.

The disclosure relates to integrated circuits including one or more rows of transistors and methods of forming rows of transistors. In an embodiment, an integrated circuit includes a row of bipolar transistors including a first semiconductor layer having a plurality of first conduction regions, a second semiconductor layer having a second conduction region, a common base between the first semiconductor layer and the second semiconductor layer, and a plurality of insulator walls extending in a first direction. The first conduction regions are separated from one another by the insulator walls. The integrated circuit further includes an insulating trench extending in a second direction and in contact with each of the bipolar transistors of the row of bipolar transistors. A conductive layer is coupled to the base, and the conductive layer extends through the insulator walls and extends at least partially into the insulating trench.