In an example, for manufacturing a semiconductor device, first dopants are implanted through a first surface section of a first surface of a silicon carbide body. A trench is formed that extends from the first surface into the silicon carbide body. The trench includes a first sidewall surface and an opposite second sidewall surface. A spacer mask is formed. The spacer mask covers at least the first sidewall surface. Second dopants are implanted through a portion of a bottom surface of the trench exposed by the spacer mask. The first dopants and the second dopants have a same conductivity type. The first dopants and the second dopants are activated. The first dopants form a doped top shielding region adjoining the second sidewall surface. The second dopants form a doped buried shielding region adjoining the bottom surface.

A semiconductor device having a high cutoff resistance capable of suppressing local current/electric field concentration and current concentration at a chip termination portion due to an electric field variation between IGBT cells due to a shape variation and impurity variation during manufacturing. The semiconductor device is characterized by including an emitter electrode formed on a front surface of a semiconductor substrate via an interlayer insulating film, a collector electrode formed on a back surface of the semiconductor substrate, a first semiconductor layer of a first conductivity type in contact with the collector electrode, a second semiconductor layer of a second conductivity type, a central area cell, and an outer peripheral area cell located outside the central area cell.

An improved silicon carbide (SiC) super junction (SJ) MOSFET having at least two buried P-shield (BPS) regions facing each other for gate oxide electric-field and saturation current reductions is disclosed. The two BPS regions are spaced apart from a body region and formed either adjoining sidewalls or below a bottom of a P column region. Moreover, a saturation current pitching (SCP) structure formed in a Junction Field Effect Transistor (JFET) region sandwiched between the two BPS regions limits saturation current of the device in a forward conduction stage for the short-circuit capability improvement.

An IGBT includes, in a single chip, an active region configured to conduct a forward load current between first and second load terminals at different sides of a semiconductor body. The active region is separated into at least first and second IGBT regions. At least 90% of the first IGBT region is configured to conduct, based on a first control signal, the forward load current. At least 90% of the second IGBT region is configured to conduct, based on a second control signal, the forward load current. A first MOS-channel-conductivity-to-area-ratio is determined by a total channel width in the first IGBT region divided by a total lateral area of first IGBT region. A second MOS-channel-conductivity-to-area-ratio is determined by a total channel width in the second IGBT region divided by a total lateral area of the second IGBT region. The second MOS-channel-conductivity-to-area-ratio amounts to less than 80% of the first MOS-channel-conductivity-to-area-ratio.

An RC IGBT includes, in a single chip, an active region configured to conduct both a forward load current and a reverse load current between a first load terminal at a front side of a semiconductor body of the RC IGBT and a second load terminal at a back side of the semiconductor body. The active region is separated into at least an IGBT-only region and an RC IGBT region. At least 90% of the IGBT-only region is configured to conduct, based on a first control signal, only the forward load current. At least 90% of the RC IGBT region is configured to conduct the reverse load current and, based on a second control signal, the forward load current.

The disclosed technology relates generally to semiconductor devices, and more particularly to semiconductor devices including a metal-oxide-semiconductor (MOS) transistor and are configured for accelerating and monitoring degradation of the gate dielectric of the MOS transistor. In one aspect, a semiconductor device configured with gate dielectric monitoring capability comprises a metal-oxide-semiconductor (MOS) transistor including a source, a drain, a gate, and a backgate region formed in a semiconductor substrate. The semiconductor device additionally comprises a bipolar junction transistor (BJT) including a collector, a base, and an emitter formed in the semiconductor substrate, wherein the backgate region of the MOS transistor serves as the base of the BJT and is independently accessible for activating the BJT. The MOS transistor and the BJT are configured to be concurrently activated by biasing the backgate region independently from the source of the MOS transistor, such that the base of the BJT injects carriers of a first charge type into the backgate region of the MOS transistor, where the first charge type is opposite charge type to channel current carriers.

NAND string configurations and semiconductor memory arrays that include such NAND string configurations are provided. Methods of making semiconductor memory cells used in NAND string configurations are also described.

A switched-mode power supply includes a power semiconductor device that includes a semiconductor body comprising transistor cells and a drift zone between a drain layer and the transistor cells, the transistor cells comprising source zones, wherein the device exhibits a first output charge gradient when a voltage between the drain layer and the source zones of the transistor cells increases from a depletion voltage of the semiconductor device to a maximum drain/source voltage of the semiconductor device, wherein the device exhibits a second output charge gradient when a voltage between the drain layer and the source zones of the semiconductor device decreases from the maximum drain/source voltage to the depletion voltage of the semiconductor device, and wherein the semiconductor device is configured such that the first output charge gradient deviates by less than 5% from the second output charge gradient.

devices and methods of forming a semiconductor device that includes a deep shielding pattern that may improve a reliability and/or a functioning of the device. An example method may include forming a wide band-gap semiconductor layer structure on a substrate, the semiconductor layer structure including a drift region that has a first conductivity type; forming a plurality of gate trenches in an upper portion of the semiconductor layer structure, the gate trenches spaced apart from each other, each gate trench having a bottom surface, a first sidewall, a second sidewall, and an upper opening; forming an obstruction over a portion of each gate trench that partially obscures the upper opening; and implanting dopants having a second conductivity type that is opposite the first conductivity type into the bottom surfaces of the gate trenches, where the dopants implanted into the bottom surface of the gate trenches form deep shielding patterns.

A semiconductor device according to an embodiment includes a gate electrode extending in a first direction, a gate insulation film that covers the gate electrode, a first semiconductor region of a first conductivity type extending in a second direction orthogonal to the first direction below the gate insulation film, and a second semiconductor region of the first conductivity type that faces the gate insulation film across the first semiconductor region. An impurity concentration of the first conductivity type of the second semiconductor region is lower than that of the first semiconductor region.