The present invention relates to a semiconductor device. The semiconductor device includes: a first main electrode provided on an active region; a second main electrode provided on an opposite side of the semiconductor substrate from the first main electrode; a protection film covering a terminal region; and a non-electrolytic plating layer provided on the first main electrode not covered by the protection film, the first main electrode includes a center electrode in a center part and an outer peripheral electrode provided along the center electrode to be separately from the center electrode, the protection film is provided to extend from the terminal region to an end edge portion of the outer peripheral electrode, the center electrode and the outer peripheral electrode include: a first metal layer; and a second metal layer provided on the first metal layer, and the outer peripheral electrode includes a hole part to reach the first metal layer.

The present disclosure provides a semiconductor device and a fabrication method thereof. The semiconductor device includes a semiconductor stack and a first ohmic contact. The semiconductor stack is formed on a substrate. The semiconductor stack has a first nitride semiconductor layer and a second nitride semiconductor layer formed on the first nitride semiconductor layer. The second nitride semiconductor layer has a wider bandgap than that of the first nitride semiconductor layer. The first ohmic contact is disposed over the semiconductor stack. The first to ohmic contact has a first opening exposing the first nitride semiconductor layer.

Integrated circuit structures having metal gates with reduced aspect ratio cuts, and methods of fabricating integrated circuit structures having metal gates with reduced aspect ratio cuts, are described. For example, an integrated circuit structure includes a sub-fin having a portion protruding above a shallow trench isolation (STI) structure. A plurality of horizontally stacked nanowires is over the sub-fin. A gate dielectric material layer is over the protruding portion of the sub-fin, over the STI structure, and surrounding the horizontally stacked nanowires. A conductive gate layer is over the gate dielectric material layer. A conductive gate fill material is over the conductive gate layer. A dielectric structure is laterally spaced apart from the plurality of horizontally stacked nanowires. A dielectric gate plug is landed on the dielectric structure.

Integrated circuit structures having backside gate partial cut or backside trench contact partial cut and/or spit epitaxial structure are described. For example, an integrated circuit structure includes a first sub-fin structure over a first stack of nanowires. A second sub-fin structure is over a second stack of nanowires. A first portion of a gate electrode is around the first stack of nanowires, a second portion of the gate electrode is around the second stack of nanowires, and a third portion of the gate electrode bridges the first and second portions of the gate electrode. A dielectric structure is between the first portion of the gate electrode and the second portion of the gate electrode, the dielectric structure over the third portion of the gate electrode. The dielectric structure is continuous along the first and second portions of the gate electrode and the first and second sub-fin structures.

Self-cooling semiconductor resistor and manufacturing method thereof are provided. The resistor comprises: multiple N-type and P-type wells in a semiconductor substrate, first polysilicon gates on each N-type well, second polysilicon gates on each P-type well, and metal interconnect layers. The multiple N-type and P-type wells are arranged alternately in row and column direction, respectively. N-type and P-type deep doped regions are formed on each N-type and P-type well, respectively. The first and second polysilicon gates are N-type and P-type deep doped respectively, and there is no gate oxide layer between the first and second polysilicon gates and the semiconductor substrate. The metal interconnect layers connect the multiple first and second polysilicon gates as an S-shaped structure. In the present application, the flow direction of heat is from the inside of the resistor to its surface, thereby realizing heat dissipation and cooling.

A semiconductor device includes a first junction-gate field-effect transistor (JFET) having a first pinch-off voltage, and a second JFET having a second pinch-off voltage higher than the first pinch-off voltage. The first JFET includes a first top gate region disposed on a surface of a substrate, a first channel region surrounding the first top gate region, and a first bottom gate region disposed under the first channel region. The second JFET includes a second top gate region disposed on the surface and having a same depth with the first top gate region relative to the surface, a second channel region surrounding the second top gate region and disposed deeper than the first channel region relative to the surface, and a second bottom gate region disposed under the second channel region and being deeper than the first bottom gate region relative to the surface.

A semiconductor device includes: a semiconductor substrate having opposing first side and second sides; an active region and an isolation region on the first side; a circuit device on the active region; a front side interconnection structure on the first side and including front side interconnection layers disposed on different levels; first and second back side interconnection structures below the second side; a buried structure having a portion disposed in the isolation region and including a conductive line; a first through-electrode structure including a first through-electrode contacting the conductive line and penetrating the semiconductor substrate between the conductive line and the first back side interconnection structure; and a second through-electrode structure including a second through-electrode penetrating the semiconductor substrate between a first front side interconnection layer and the second back side interconnection structure. The first front side interconnection layer is on a level higher than that of the conductive line.

A semiconductor device comprising a plurality of nanosheet transistor channels adjacent to a source/drain. An inner spacer located between each of the plurality of nanosheet transistor channels and the inner spacer wraps around the end of each of the plurality of nanosheet transistors, wherein the source/drain is in contact with the inner spacer and each of the plurality of nanosheet transistor channels. A gate surrounding each of the plurality of nanosheet transistor channels and an electrical contact connected to the source/drain. An ultra low-k spacer located between the gate and the source/drain, wherein the ultra low-k spacer reduces the parasitic capacitance of the nanosheet transistor.

A field effect transistor includes a source region and a drain region formed within and/or above openings in a dielectric capping mask layer overlying a semiconductor substrate and a gate electrode. A source-side silicide portion and a drain-side silicide portion are self-aligned to the source region and to the drain region, respectively.

A semiconductor device includes an active region on a substrate, gate structures intersecting the active region on the substrate, source/drain regions on both sides of the gate structures, a contact structure in a contact hole exposing the source/drain regions, the contact structure comprising a barrier layer and a plug layer, and an insulating pattern in a remaining space of the contact hole, wherein the contact structure includes a first portion filling a lower portion of the contact hole and a second portion protruding from a region of the first portion, the plug layer extends continuously from the first portion to the second portion, and the barrier layer of the second portion has upper ends at a level lower than an upper surface of the plug layer of the second portion on both sides of the plug layer of the second portion.