A power semiconductor device and a method of manufacturing a power semiconductor device is provided, including a shield gate trench (SGT) metal-oxide semiconductor field-effect transistor (MOSFET). The present disclosure provides for a MOSFET with a reduced charge between the gate conductive region and the drain or collector region, in order to improve the switching efficiency of the MOSFET.

A semiconductor device includes first nanostructures vertically separated from one another, a first gate structure wrapping around each of the first nanostructures, and second nanostructures vertically separated from one another. The semiconductor device also includes a second gate structure wrapping around the second nanostructures, a first drain/source structure coupled to a first end of the first nanostructures, a second drain/source structure coupled to both of a second end of the first nanostructures and a first end of the second nanostructures, and a third drain/source structure coupled to a second end of the second nanostructures. The first drain/source structure has a first doping type, the second and third drain/source structures have a second doping type, and the first doping type is opposite to the second doping type.

The disclosure, belonging to the technological field of semiconductor memory, specifically relates to a semi-floating-gate device which comprises at least a semiconductor substrate, a source region, a drain region, a floating gate, a control gate, a perpendicular channel region and a gated p-n junction diode used to connect the floating gate and the substrate. The semi-floating-gate device disclosed in the disclosure using the floating gate to store information and realizing charging or discharging of the floating gate through a gated p-n junction diode boasts small unit area, high chip density, low operating voltage in data storage and strong ability in data retain.

According to one embodiment, a semiconductor device is provided. The semiconductor device has a first region formed of semiconductor and a second region formed of semiconductor which borders the first region. An electrode is formed to be in ohmic-connection with the first region. A third region is formed to sandwich the first region. A first potential difference is produced between the first and the second regions in a thermal equilibrium state, according to a second potential difference between the third region and the first region.

A transparent electrode including: a substrate; a first layer disposed on the substrate, the first layer including a graphene mesh structure, the graphene mesh structure including graphene and a plurality of holes; and a second layer disposed on the first layer, wherein the second layer includes a plurality of conductive nanowires.

A semiconductor chip has a semiconductor body with a bottom side and a top side arranged distant from the bottom side in a vertical direction, an active and a non-active transistor region, a drift region formed in the semiconductor body, a contact terminal for externally contacting the semiconductor chip, and a plurality of transistor cells formed in the semiconductor body. Each of the transistor cells has a first electrode. Each of a plurality of connection lines electrically connects another one of the first electrodes to the contact terminal pad at a connecting location of the respective connection line. Each of the connection lines includes a resistance section formed of a locally increased specific resistance relative to a specific resistance of adjacent semiconductor material or metal of the respective connection line. Each of the connecting locations and each of the resistance sections is arranged in the non-active transistor region.

A semiconductor device is formed by forming a deep trench in a substrate and a dielectric liner on sidewalls of the deep trench. A first undoped polysilicon layer is formed on the semiconductor device, extending into the deep trench on the dielectric liner, but not filling the deep trench. Dopants are implanted into the first polysilicon layer. A second layer of polysilicon is formed on the first layer of polysilicon. A thermal drive anneal activates and diffuses the dopants. In one version, the dielectric liner is removed at the bottom of the deep trench before the first polysilicon layer is formed, so that the polysilicon in the deep trench provides a contact to the substrate. In another version, the polysilicon in the deep trench is isolated from the substrate by the dielectric liner.

A semiconductor device comprises: a semiconductor device active region; an electrode shape controlling layer disposed on the semiconductor device active region, the electrode shape controlling layer containing aluminum, the content of aluminum being changed in a direction from bottom to up from the semiconductor device active region, an electrode region being disposed on the electrode shape controlling layer, a groove extended toward the semiconductor device active region and penetrating through the electrode shape controlling layer longitudinally being disposed in the electrode region, all or part of a side surface of the groove having a shape corresponding to the content of aluminum in the electrode shape controlling layer; and an electrode disposed in the groove in the electrode region entirely or partially, the electrode having a shape matching with the shape of the groove, a bottom portion of the electrode being contacted with the semiconductor device active region.

Semiconductor devices and methods for forming semiconductor devices are provided. A vertical channel structure extends from a substrate and is formed as a channel between a source region and a drain region. A first metal gate surrounds a portion of the vertical channel structure and has a gate length. The first metal gate has a first gate section with a first workfunction and a first thickness. The first metal gate also has a second gate section with a second workfunction and a second thickness. The first thickness is different from the second thickness, and the sum of the first thickness and the second thickness is equal to the gate length. A ratio of the first thickness to the second thickness is chosen to achieve a desired threshold voltage level for the semiconductor device.

One illustrative device disclosed herein includes a stepped conductive source/drain structure with a cavity defined therein, the cavity being located vertically above an active region, a non-conductive structure positioned in the cavity, a layer of insulating material positioned above the gate structure, the stepped conductive source/drain structure and the non-conductive structure, a gate contact opening defined in the layer of insulating material and a conductive gate contact positioned in the gate contact opening that is conductively coupled to the gate structure, wherein at least a portion of the conductive gate contact is positioned vertically above the non-conductive structure.