A semiconductor device including an active region protruding from an upper surface of a substrate and extending in a first horizontal direction, at least two gate electrodes extending in a second horizontal direction and crossing the active region, the second horizontal direction crossing the first horizontal direction, a source/drain region in the active region between the gate electrodes may be provided. The source/drain region includes a recess region, an outer doped layer on an inner wall of the recess region, an intermediate doped layer on the outer doped layer, and an inner doped layer on the intermediate doped layer and filling the recess region. One of the outer doped layer or the intermediate doped layer includes antimony, and the inner doped layer includes phosphorous.

A semiconductor product comprising: a first semiconductor electrode, a second semiconductor electrode and an interconnecting semiconductor electrode defining a third semiconductor electrode; a first switch, between the first semiconductor electrode and the third semiconductor electrode, provided by a first vertical insulated-gate field-effect-transistor; and a second switch, between the second semiconductor electrode and the third semiconductor electrode, provided by a second vertical insulated-gate field-effect-transistor, wherein the interconnecting semiconductor electrode interconnects the first vertical insulated gate field-effect-transistor and the second vertical insulated gate field-effect-transistor.

A lateral double-diffused metal-oxide-semiconductor field effect (LDMOS) transistor includes a silicon semiconductor structure, a dielectric layer at least partially disposed in a trench of the silicon semiconductor structure in a thickness direction, and a gate conductor embedded in the dielectric layer and extending into the trench in the thickness direction. The dielectric layer and the gate conductor are at least substantially symmetric with respect to a center axis of the trench extending in the thickness direction, as seen when the LDMOS transistor is viewed cross-sectionally in a direction orthogonal to the lateral and thickness directions.

An electronic device can include a semiconductor layer, an insulating layer overlying the semiconductor layer, and a conductive electrode. In an embodiment, a first conductive electrode member overlies the insulating layer, and a second conductive electrode member overlies and is spaced apart from the semiconductor layer. The second conductive electrode member has a first end and a second end opposite the first end, wherein each of the semiconductor layer and the first conductive electrode member are closer to the first end of the second conductive electrode member than to the second end of the second conductive electrode member. In another embodiment, the conductive electrode can be substantially L-shaped. In a further embodiment, a process can include forming the first and second conductive electrode members such that they abut each other. The second conductive electrode member can have the shape of a sidewall spacer.

A semiconductor device includes a semiconductor substrate, a body region disposed in the semiconductor substrate and having a first conductivity type, a composite source region disposed in the semiconductor substrate adjacent the body region and having a second conductivity type, and a gate structure supported by the semiconductor substrate and having a side adjacent the composite source region. The composite source region includes a plurality of first constituent source regions disposed along the side of the gate structure and having the second conductivity type, and a second constituent source region disposed along the side of the gate structure and between two first constituent source regions of the plurality of first constituent source regions, the second constituent source region having the second conductivity type. The second constituent source region has a different dopant concentration level than the plurality of first constituent source regions.

A semiconductor device includes: a semiconductor region having charge carriers of a first conductivity type; a transistor cell in the semiconductor region; a semiconductor channel region in the transistor cell and having a first doping concentration of charge carriers of a second conductivity type, wherein a transition between the semiconductor channel region and the semiconductor region forms a first pn-junction; a semiconductor auxiliary region in the semiconductor region and having a second doping concentration of charge carriers of the second conductivity type. A transition between the semiconductor auxiliary region and semiconductor region forms a second pn-junction positioned deeper in the semiconductor region as compared to the first pn-junction. The semiconductor auxiliary region is positioned closest to the semiconductor channel region as compared to any other semiconductor region having charge carriers of the second conductivity type and that forms a further pn-junction with the semiconductor region.

Embodiments of a transistor control device for controlling a bi-directional power transistor are disclosed. In an embodiment, a transistor control device for controlling a bi-directional power transistor includes a resistor connectable to a body terminal of the bi-directional power transistor and a transistor body switch circuit connectable to the resistor, to a drain terminal of the bi-directional power transistor, and to a source terminal of the bi-directional power transistor. The transistor body switch circuit includes switch devices and alternating current (AC) capacitive voltage dividers connected to control terminals of the switch devices. The AC capacitive voltage dividers are configured to control the switch devices to switch a voltage of the body terminal of the bi-directional power transistor as a function of a voltage between the drain terminal of the bi-directional power transistor and the source terminal of the bi-directional power transistor.

Provided are a semiconductor device, the semiconductor device comprise, a substrate which comprises a first surface and a second surface facing the first surface, an epitaxial layer which is formed on the first surface of the substrate and has a first conductivity type, a base region which is formed in the epitaxial layer and has a second conductivity type different from the first conductivity type, a source region which is formed in the base region and has the first conductivity type, a channel region which is formed in the base region to be separated from the source region and has the first conductivity type and a barrier region which is formed between the source region and the channel region and has the second conductivity type

A device is described herein. The device comprises a unit cell of a silicon carbide (SiC) substrate. The unit cell comprises: a trench in a well region having a second conduction type. The well region is in contact with a region having a first conduction type to form a p-n junction. A width of the trench is less than 1.0 micrometers (μm). A width of the unit cell is one of less than and equal to 5.0 micrometers (μm). The device comprises a source region comprising the first conduction type. The device further comprises a metal oxide semiconductor field effect transistor component. The device described herein comprises a reduced unit cell pitch and reduced channel resistance without any compromise in channel length. The device comprises an ILD opening greater than or equal to width of the trench.

A silicon carbide device includes a transistor cell with a front side doping region, a body region, and a drift region. The body region includes a first portion having a first average net doping concentration and a second portion having a second average net doping concentration. The first portion and the second portion have an extension of at least 50 nm in a vertical direction. The first average net doping concentration is at least two times the second average net doping concentration, and the first average net doping concentration is at least 1.Math.10.sup.17 cm.sup.−3.