A switching device according to the present invention is a switching device for switching a load by on-off control of voltage, and includes an SiC semiconductor layer where a current path is formed by on-control of the voltage, a first electrode arranged to be in contact with the SiC semiconductor layer, and a second electrode arranged to be in contact with the SiC semiconductor layer for conducting with the first electrode due to the formation of the current path, while the first electrode has a variable resistance portion made of a material whose resistance value increases under a prescribed high-temperature condition for limiting current density of overcurrent to not more than a prescribed value when the overcurrent flows to the current path.

A switching device according to the present invention is a switching device for switching a load by on-off control of voltage, and includes an SiC semiconductor layer where a current path is formed by on-control of the voltage, a first electrode arranged to be in contact with the SiC semiconductor layer, and a second electrode arranged to be in contact with the SiC semiconductor layer for conducting with the first electrode due to the formation of the current path, while the first electrode has a variable resistance portion made of a material whose resistance value increases under a prescribed high-temperature condition for limiting current density of overcurrent to not more than a prescribed value when the overcurrent flows to the current path.

A thin film transistor array substrate and an electronic device including the thin film transistor array are disclosed. The thin film transistor comprises a substrate, a first active layer on the substrate, a gate electrode on the first active layer, a second active layer on the gate electrode such that the gate electrode is between the first active layer and the second active layer. The gate electrode is configured to drive the first active layer and the second active layer. Thereby, it is possible to provide the thin film transistor array substrate including one or more thin film transistors having high current characteristics in a small area, and the electronic device including the thin film transistor array substrate.

A semiconductor device includes a gate structure disposed over a substrate, and a first dielectric layer disposed over the substrate, including and over the gate structure. A first metal feature is disposed in the first dielectric layer, including an upper portion having a first width and a lower portion having a second width that is different than the first width. A dielectric spacer is disposed along the lower portion of the first metal feature, wherein the upper portion of the first metal feature is disposed over the dielectric spacer. A second dielectric layer is disposed over the first dielectric layer, including over the first metal feature and a second metal feature extends through the second dielectric layer to physically contact with the first metal feature. A third metal feature extends through the second dielectric layer and the first dielectric layer to physically contact the gate structure.

There is provided a semiconductor device comprising at least, a crystalline oxide semiconductor layer which has a band gap of 4.5 eV or more; and a field-effect mobility of 10 cm.sup.2V.Math.s or higher.

In some embodiments, a semiconductor device comprises a semiconductor die comprising a vertical transistor device having a source electrode, a drain electrode and a gate electrode, the semiconductor die having a first surface and a second surface opposing the first surface. A first metallization structure is located on the first surface and comprises at least one source pad coupled to the source electrode, at least one drain pad coupled to the drain electrode and at least one gate pad coupled to the gate electrode. A second metallization structure is located on the second surface and comprises a conductive structure and an electrically insulating layer and forms an outermost surface of the semiconductor device. The outermost surface of the second metallization structure is electrically insulated from the semiconductor die by the electrically insulating layer.

In an example, a transistor device is provided. The transistor device includes a plurality of transistor cells each including a gate electrode and each at least partially integrated in a semiconductor body that includes a wide bandgap semiconductor material. The transistor device includes a gate pad arranged on top of the semiconductor body, and a plurality of gate runners each arranged on top of the semiconductor body and each connected to gate electrodes of at least some of the plurality of transistor cells. Each gate runner of the plurality of gate runners has a longitudinal direction, and at least one of the gate runners includes at least a section in which a resistivity per area increases in the longitudinal direction as a distance to the gate pad along the gate runner increases.

A vertical-conduction MOSFET device formed in a body of silicon carbide having a first and a second face and a peripheral zone. A drain region, of a first conductivity type, extends in the body between the two faces. A body region, of a second conductivity type, extends in the body from the first face, and a source region, having the first conductivity type, extends to the inside of the body region from the first face of the body. An insulated gate region extends on the first face of the body and comprises a gate conductive region. An annular connection region, of conductive material, is formed within a surface edge structure extending on the first face of the body, in the peripheral zone. The gate conductive region and the annular connection region are formed by a silicon layer and by a metal silicide layer overlying the silicon layer.

In some embodiments, a semiconductor device includes a semiconductor die including a vertical transistor device having a source electrode, a drain electrode and a gate electrode, the semiconductor die having a first surface and a metallization structure. The metallization structure includes a first conductive layer above the first surface, a first insulating layer above the first conductive layer, a second conductive layer above the first insulating layer, a second insulating layer above the second conductive layer and a third conductive layer above the second insulting layer. The third conductive layer includes at least one source pad electrically coupled to the source electrode, at least one drain pad electrically coupled to the drain electrode and at least one gate pad electrically coupled to the gate electrode.

A semiconductor device includes an active region, a LOCOS region formed within the active region and that extends vertically above a top surface of the active region, a gate region formed above the top surface of the active region, and a polysilicon resistor having a bottom surface that is offset vertically and physically isolated from a top surface of the LOCOS region. The active region includes a source region laterally disposed from the gate region, a drain region laterally disposed from the gate region, and a drift region laterally disposed between the gate region and the drain region. The polysilicon resistor is formed above the drift region. The active region further includes a first charge balance region formed in the active region below the drift region.