In one embodiment, a cascode rectifier structure includes a group III-V semiconductor structure includes a heterostructure disposed on a semiconductor substrate. A first current carrying electrode and a second current carrying electrode are disposed adjacent a major surface of the heterostructure and a control electrode is disposed between the first and second current carrying electrode. A rectifier device is integrated with the group III-V semiconductor structure and is electrically connected to the first current carrying electrode and to a third electrode. The control electrode is further electrically connected to the semiconductor substrate and the second current path is generally perpendicular to a primary current path between the first and second current carrying electrodes. The cascode rectifier structure is configured as a two terminal device.

A semiconductor packaging structure includes a chip, a first pin, a second pin, and a third pin. The chip includes a first surface, a second surface, a first power switch, and a second switch, and both the first power switch and the second switch include a first terminal and a second terminal. The second surface of the chip is opposite to the first surface of the chip. The first pin does not contact to the second pin. The first terminal of the first power switch of the chip is coupled to the first pin, and the second terminal of the first power switch of the chip is coupled to the third pin. The first terminal of the second power switch of the chip is coupled to the third pin, and the second terminal of the second power switch of the chip is coupled to the second pin.

One illustrative method disclosed includes, among other things, forming an initial conductive source/drain structure that is conductively coupled to a source/drain region of a transistor device, performing a recess etching process on the initial conductive source/drain structure to thereby define a stepped conductive source/drain structure with a cavity defined therein, forming a non-conductive structure in the cavity, forming a layer of insulating material above the gate structure, the stepped conductive source/drain structure and the non-conductive structure, forming a gate contact opening in the layer of insulating material and forming a conductive gate contact in the gate contact opening that is conductively coupled to the gate structure.

To enhance electromigration resistance of an electrode.

A drain electrode is partially formed on a side surface of a drain pad. In this case, the drain electrode is integrated with the drain pad and extends from the side surface of the drain pad in a first direction (y direction). A recessed portion is located in a region overlapping with the drain electrode in a plan view. At least a part of the drain electrode is buried in the recessed portion. A side surface of the recessed portion, which faces the drain pad, enters the drain pad in the first direction (y direction).

A semiconductor device includes a plurality of first field-effect structures each including a polysilicon gate arranged on and in contact with a first gate dielectric, and a plurality of second field-effect structures each including a metal gate arranged on and in contact with a second gate dielectric. The plurality of first field-effect structures and the plurality of second field-effect structures form part of a power semiconductor device.

High-voltage, gallium-nitride HEMTs are described that are capable of withstanding reverse-bias voltages of at least 900 V and, in some cases, in excess of 2000 V with low reverse-bias leakage current. A HEMT may comprise a lateral geometry having a gate, a thin insulating layer formed beneath the gate, a gate-connected field plate, and a source-connected field plate.

Microelectronic structures embodying the present invention include a field effect transistor (FET) having highly conductive source/drain extensions. Formation of such highly conductive source/drain extensions includes forming a passivated recess which is back filled by epitaxial deposition of doped material to form the source/drain junctions. The recesses include a laterally extending region that underlies a portion of the gate structure. Such a lateral extension may underlie a sidewall spacer adjacent to the vertical sidewalls of the gate electrode, or may extend further into the channel portion of a FET such that the lateral recess underlies the gate electrode portion of the gate structure. In one embodiment the recess is back filled by an in-situ epitaxial deposition of a bilayer of oppositely doped material. In this way, a very abrupt junction is achieved that provides a relatively low resistance source/drain extension and further provides good off-state subthreshold leakage characteristics. Alternative embodiments can be implemented with a back filled recess of a single conductivity type.

A semiconductor device includes first, second, third, and fourth electrodes, a first insulating film, and first, second third, and fourth silicon carbide layers. A first distance between the first electrode and a first interface between the fourth electrode and fourth silicon carbide region is longer than a second distance between the first insulating film and a second interface between the third silicon carbide region and the fourth silicon carbide region. The fourth silicon carbide region is between the third silicon carbide region and the second silicon carbide region in a direction perendicular to the second interface.

The characteristics of a semiconductor device are improved. A semiconductor device has a potential fixed layer containing a p type impurity, a channel layer, and a barrier layer, formed over a substrate, and a gate electrode arranged in a trench penetrating through the barrier layer, and reaching some point of the channel layer via a gate insulation film. Source and drain electrodes are formed on opposite sides of the gate electrode. The p type impurity-containing potential fixed layer has an inactivated region containing an inactivating element such as hydrogen between the gate and drain electrodes. Thus, while raising the p type impurity (acceptor) concentration of the potential fixed layer on the source electrode side, the p type impurity of the potential fixed layer is inactivated on the drain electrode side. This can improve the drain-side breakdown voltage while providing a removing effect of electric charges by the p type impurity.

Techniques relate to contacts for semiconductors. First gate contacts are formed on top of first gates, second gate contacts are on second gates, and terminal contacts are on silicide contacts. First gate contacts and terminal contacts are recessed to form a metal layer on top. Second gate contacts are recessed to be separately on each of the second gates. Filling material is formed on top of the recessed second gate contacts and metal layer. An upper layer is on top of the filling material. First metal vias are formed through filling and upper layers down to metal layer over first gate contacts. Second metal vias are formed through filling and upper layers down to metal layer over terminal contacts. Third metal vias are formed through filling and upper layers down to recessed second gate contacts over second gates. Third metal vias are taller than first.