A semiconductor device including a well resistance element of high accuracy and high withstand voltage and a method of manufacturing the semiconductor device are provided. The semiconductor device includes a semiconductor substrate, a well region, an input terminal, an output terminal, a separation insulating film, and an active region. The input terminal and the output terminal are electrically coupled to the well region. The separation insulating film is arranged to be in contact with the upper surface of the well region in an intermediate region between the input terminal and the output terminal. The active region is arranged to be in contact with the upper surface of the well region. The separation insulating film and the active region in the intermediate region have an elongated shape in plan view. In the intermediate region, a plurality of separation insulating films and a plurality of active regions are alternately and repeatedly arranged.

An integrated electronic device includes a semiconductive film above a buried insulating layer that is situated above a supporting substrate. An active zone is delimited within the semiconductive film. A MOS transistor supported within the active zone includes a gate region situated above the active zone. The gate region includes a rectilinear part situated between source and drain regions. The gate region further includes a forked part extending from the rectilinear part. A raised semiconductive region situated above the active zone is positioned at least partly between portions of the forked part. A substrate contact for the transistor is electrically coupled to the raised semiconductive region.

A semiconductor device comprises: a substrate; a multi-layer semiconductor layer located on the substrate, the multi-layer semiconductor layer being divided into an active area and a passive area outside the active area; a gate electrode, a source electrode and a drain electrode all located on the multi-layer semiconductor layer and within the active area; and a heat dissipation layer covering at least one portion of the active area and containing a heat dissipation material. In embodiments of the present invention, a heat dissipation layer covering at least one portion of the active area is provided in the semiconductor device. The arrangement of the heat dissipation layer adds a heat dissipation approach for the semiconductor device in the planar direction, thus the heat dissipation effect of the semiconductor device is improved.

The present disclosure relates to semiconductor devices and the teachings thereof may be embodied in metal oxide semiconductor field effect transistors (MOSFET). Some embodiments may include a power MOSFET with transistor cells, each cell comprising a source and a drain region; a first dielectric layer disposed atop the transistor cells; a silicon rich oxide layer on the first dielectric layer; grooves through the multi-layered dielectric, each groove above a respective source or drain region and filled with a conductive material; a second dielectric layer atop the multi-layered dielectric; openings in the second dielectric layer, each opening exposing a contact area of one of the plurality of grooves; and a metal layer disposed atop the second dielectric layer and filling the openings. The metal layer may form at least one drain metal wire and at least one source metal wire. The at least one drain metal wire may connect two drain regions through respective grooves. The at least one source metal wire may connect two source regions through respective grooves. Each groove has a length extending from the at least one drain metal wire to the at least one source metal wire in an adjacent pair.

A semiconductor device includes a semiconductor substrate having an inactive area and a pair of active areas separated by the inactive area, a control terminal supported by the semiconductor substrate and extending across the pair of active areas and the inactive area to define a conduction path during operation between a first conduction region in each active area and a second conduction region in each active area, a conduction terminal supported by the semiconductor substrate and extending across the pair of active areas and the inactive area for electrical connection to each first conduction region, and a via extending through the semiconductor substrate, electrically connected to the conduction terminal, and positioned in the inactive area.

Embodiments of the present invention are directed to a method for forming a complementary field effect transistor (CFET) structure having a wrap-around contact. In a non-limiting embodiment of the invention, a complementary nanosheet stack is formed over a substrate. The complementary nanosheet stack includes a first nanosheet and a second nanosheet separated by a dielectric spacer. A first sacrificial layer is formed over a source or drain (S/D) region of the first nanosheet and a second sacrificial layer is formed over a S/D region of the second nanosheet. A conductive gate is formed over channel regions of the first nanosheet and the second nanosheet. After the conductive gate is formed, the first sacrificial layer is replaced with a first wrap-around contact and the second sacrificial layer is replaced with a second wrap-around contact.

A semiconductor device includes a codoped layer, a channel layer, a barrier layer, and a gate electrode disposed in a trench extending through the barrier layer and reaching a middle point in the channel layer via a gate insulating film. On both sides of the gate electrode, a source electrode and a drain electrode are formed. On the source electrode side, an n-type semiconductor region is disposed to fix a potential and achieve a charge removing effect while, on the drain electrode side, a p-type semiconductor region is disposed to improve a drain breakdown voltage. By introducing hydrogen into a region of the codoped layer containing Mg as a p-type impurity in an amount larger than that of Si as an n-type impurity where the n-type semiconductor region is to be formed, it is possible to inactivate Mg and provide the n-type semiconductor region.

A switch element includes a source having a plurality of source fingers and a drain having a plurality of drain fingers interleaved with the source fingers. An active mesa region is defined between at least one of the plurality of source fingers and an adjacent at least one of the plurality of drain fingers. A plurality of gates are disposed between the at least one of the plurality of source fingers and the adjacent at least one of the plurality of drain fingers. At least one of gates extends into the active mesa region from outside of the active mesa region and terminates within the active mesa region.

A semiconductor device includes a drift layer disposed on a substrate. The drift layer has a non-planar surface having a plurality of repeating features oriented parallel to a length of a channel of the semiconductor device. Further, each the repeating features have a dopant concentration higher than a remainder of the drift layer.

A semiconductor device includes a gate structure, a source region and a drain region. The source region and the drain region are on opposite sides of the gate structure. The source region includes a first region of a first conductivity type and a second region of a second conductivity type. The second conductivity type is opposite to the first conductivity type. The first region is between the second region and the gate structure. The second region includes at least one projection protruding into the first region and toward the gate structure.