Various embodiments of the present disclosure are directed towards a semiconductor device. The semiconductor device comprises a source region and a drain region in a substrate and laterally spaced. A gate stack is over the substrate and between the source region and the drain region. The drain region includes two or more first doped regions having a first doping type in the substrate. The drain region further includes one or more second doped regions in the substrate. The first doped regions have a greater concentration of first doping type dopants than the second doped regions, and each of the second doped regions is disposed laterally between two neighboring first doped regions.

Wide bandgap trench gate semiconductor devices are provided. In one example, a semiconductor device includes a wide bandgap semiconductor structure. The wide bandgap semiconductor structure includes a drift region of a first conductivity type and a well region of a second conductivity type. The semiconductor device includes a gate trench in the wide bandgap semiconductor structure. The gate trench extends through the well region into the drift region. The semiconductor device includes a buried gate structure in the gate trench. The buried gate structure includes a gate polysilicon layer and a gate silicide layer.

An integrated circuit structure includes a semiconductor substrate, first and second source/drain features, a gate dielectric layer, a gate electrode, a field plate electrode, first and second metal silicide layers, a dielectric layer, and a spacer. The gate electrode and the field plate electrode are over the gate dielectric layer and respectively vertically overlapping a well region and a drift region in the semiconductor substrate. A first sidewall of the field plate electrode faces the gate electrode. The first and second metal silicide layers are over the gate electrode and the field plate electrode, respectively. The dielectric layer has a first portion between the gate electrode and the first sidewall of the field plate electrode and a second portion below a bottom surface of the field plate electrode. The spacer is alongside a second sidewall of the field plate electrode and over the second portion of the dielectric layer.

A semiconductor device includes a fin-shaped semiconductor layer on a semiconductor substrate. A first insulating film is around the fin-shaped semiconductor layer and a pillar-shaped semiconductor layer is on the fin-shaped semiconductor layer. A gate insulating film is around the pillar-shaped semiconductor layer. A metal gate electrode is around the gate insulating film and a metal gate line is connected to the metal gate electrode. A metal gate pad is connected to the metal gate line, and a width of the metal gate electrode and a width of the metal gate pad is larger than a width of the metal gate line.

A semiconductor device and method of making the same are disclosed. The semiconductor device includes a memory gate on a charge storage structure formed on a substrate, a select gate on a gate dielectric on the substrate proximal to the memory gate, and a dielectric structure between the memory gate and the select gate, and adjacent to sidewalls of the memory gate and the select gate, wherein the memory gate and the select gate are separated by a thickness of the dielectric structure. Generally, the dielectric structure comprises multiple dielectric layers including a first dielectric layer adjacent the sidewall of the memory gate, and a nitride dielectric layer adjacent to the first dielectric layer and between the memory gate and the select gate. Other embodiments are also disclosed.

A semiconductor device and a method of fabricating the same, the semiconductor device includes a substrate, a first gate and a second gate. The first gate is disposed on the substrate and includes a first gate insulating layer, a polysilicon layer, a silicide layer and a protective layer stacked with each other on the substrate and a first spacer surrounds the first gate insulating layer, the polysilicon layer, the silicide layer and the protective layer. The second gate is disposed on the substrate and includes a second gate insulating layer, a work function metal layer and a conductive layer stacked with each other on the substrate, and a second spacer surrounds the second gate insulating layer, the work function metal layer and the conductive layer.

An integrated circuit includes a silicon-on-insulator substrate that includes a semiconductor film located above a buried insulating layer. A first electrode of a silicide material overlies the semiconductor film. A sidewall insulating material is disposed along sidewalls of the first electrode. A dielectric layer is located between the first electrode and the semiconductor film. A second electrode includes a silicided zone of the semiconductor film, which is located alongside the sidewall insulating material and extends at least partially under the dielectric layer and the first electrode. The first electrode, the dielectric layer and the second electrode form a capacitor that is part of a circuit of the integrated circuit.

A semiconductor device with improved characteristics is provided. The semiconductor device includes a LDMOS, a source plug electrically coupled to a source region of the LDMOS, a source wiring disposed over the source plug, a drain plug electrically coupled to a drain region of the LDMOS, and a drain wiring disposed over the drain plug. The structure of the source plug of the semiconductor device is devised. The semiconductor device is structured such that the drain plug is linearly disposed to extend in a direction Y, and the source plug includes a plurality of separated source plugs arranged at predetermined intervals in the direction Y. In this way, the separation of the source plug decreases an opposed area between the source plug and the drain plug, and can thus decrease the parasitic capacitance therebetween.

A MOS transistor structure for matched operation in weak-inversion or sub-threshold range (e.g. input-pair of operational amplifier, comparator, and/or current-mirror) is disclosed. The transistor structure may include a well region of any impurity type in a substrate (SOI is included). The well-region can even be represented by the substrate itself. At least one transistor is located in the well region, whereby the active channel-region of the transistor is independent from lateral isolation interfaces between GOX (gate oxide) and FOX (field oxide; including STI-shallow trench isolation).

In one aspect, methods of silicidation and germanidation are provided. In some embodiments, methods for forming metal silicide can include forming a non-oxide interface, such as germanium or solid antimony, over exposed silicon regions of a substrate. Metal oxide is formed over the interface layer. Annealing and reducing causes metal from the metal oxide to react with the underlying silicon and form metal silicide. Additionally, metal germanide can be formed by reduction of metal oxide over germanium, whether or not any underlying silicon is also silicided. In other embodiments, nickel is deposited directly and an interface layer is not used. In another aspect, methods of depositing nickel thin films by vapor phase deposition processes are provided. In some embodiments, nickel thin films are deposited by ALD.