In a general aspect, an apparatus can include a semiconductor substrate, a drift region disposed in the semiconductor substrate; a body region disposed in the drift region and a source region disposed in the body region. The apparatus can also include a gate trench disposed in the semiconductor substrate. The apparatus can further include a gate dielectric disposed on a sidewall and a bottom surface of the gate trench, the gate dielectric on the sidewall defining a first interface with the body region and the gate dielectric on the bottom surface defining a second interface with the body region. The apparatus can still further include a gate electrode disposed on the gate dielectric and a lateral channel region disposed in the body region, the lateral channel region being defined along the second interface.

A method includes forming a first isolation region in a substrate, wherein a top surface of the first isolation region is lower than a top surface of the substrate, depositing a gate electrode layer over the substrate and patterning the gate electrode layer to form a first gate electrode region and a second gate electrode region, wherein the second gate electrode region is vertically aligned with the first isolation region and the first gate electrode region is immediately adjacent to the second gate electrode region.

An electric assembly includes a semiconductor switching device with a maximum breakdown voltage rating across two load terminals in an off-state. A clamping diode is electrically connected to the two load terminals and parallel to the switching device. A semiconductor body of the clamping diode is made of silicon carbide. An avalanche voltage of the clamping diode is lower than the maximum breakdown voltage rating of the switching device.

Power devices using refilled trenches with permanent charge at or near their sidewalls. These trenches extend vertically into a drift region.

Apparatus and methods for regulated voltage distribution are disclosed. Distribution elements can pass a regulated voltage provided by a single voltage regulator to thereby distribute the regulated voltage. A distribution element of the distribution elements can be included in a feedback path that provides a feedback signal to an input of the voltage regulator. The voltage regulator can be a low dropout voltage regulator, for example. The regulated voltage can be used in a variety of applications, for example, as a bias voltage for a power amplifier.

Disclosed are a bidirectional power device and a method for manufacturing the same. The bidirectional power device includes a semiconductor layer, a plurality of trenches located in the semiconductor layer, a gate dielectric layer located on an inner wall of each of the plurality of trenches, a control gate located at a lower portion of each of the plurality of trenches, a shield gate located at an upper portion of each of the plurality of trenches and an isolation layer located between the control gate and the shield gate. When the bidirectional power device is turned off, charges of a source region and a drain region are depleted by the shield gate through a shield dielectric layer, thereby improving voltage withstand property. When the bidirectional power device is turned on, the source region and/or the drain region and the semiconductor layer provide a low-impedance conduction path.

The application refers to a semiconductor device including: a semiconductor body having a first surface and a second surface; an active region having at least one semiconductor cell configured to conduct a load current between the first surface and the second surface; an edge termination region separating the active region from a chip edge; and a first layer within at least a part of the edge termination region. The first layer includes silicon, nitrogen and hydrogen. In atomic numbers, a ratio of the silicon to the nitrogen is at least 3.3 to 4 in at least a portion of the first layer. At least the portion of the first layer includes at most 16 percent hydrogen in atomic numbers.

A semiconductor device includes trench portions arrayed in a first direction on an upper surface side of a semiconductor substrate, a first conductivity type lower surface region provided in a part of a lower surface of the semiconductor substrate, a second conductivity type base region provided on the upper surface side, a first conductivity type first region disposed between the base region and the lower surface region, a first conductivity type upper surface region provided on an upper surface of the semiconductor substrate, and a second conductivity type bottom region disposed continuously in the first direction to be in contact with bottom portions of the trench portions. In a cross section along the first direction and perpendicular to the upper and lower surfaces and passing through the lower surface region, one end portion of the bottom region in the first direction locates directly above the lower surface region.

An LDMOS having multiple field plates and manufacturing method. The LDMOS has a semiconductor substrate with an upper surface, an interlayer dielectric layer with an upper surface, a gate conducting layer, a field plate barrier layer, a first field plate and a second field plate. The gate conducting layer has a plate portion and a channel portion, the height of the plate portion to the upper surface of the semiconductor substrate is greater than the height of the channel portion to the upper surface of the semiconductor substrate. The field plate barrier layer disposes in the interlayer dielectric layer between the plate portion and the drain. The first field plate disposes in the interlayer dielectric layer and extends from the field plate barrier layer through the interlayer dielectric layer to the upper surface of the interlayer dielectric layer. The second field plate disposes in the interlayer dielectric layer and extends from the field plate barrier layer through the interlayer dielectric layer to the upper surface of the interlayer dielectric layer.

A power semiconductor device includes an epitaxial layer of a first conductivity type, a first doped region of a second conductivity type, a second doped region of the first conductivity type, a contact metal layer, a device electrode, a first termination electrode, and a second termination electrode. The epitaxial layer includes an active region and a termination region. The device electrode is located in a device trench in the active region, and is electrically isolated from the epitaxial layer and the contact metal layer. The first termination electrode is located in a first termination trench in the termination region and is electrically isolated from the epitaxial layer. The second termination electrode is located at a bottom of the first termination trench and is electrically isolated from the first termination electrode and the epitaxial layer. Both the first termination electrode and the second termination electrode are capable of being selectively floating.