A semiconductor device includes a semiconductor layer structure of a wide band-gap semiconductor material. The semiconductor layer structure includes a drift region having a first conductivity type and a well region having a second conductivity type. A plurality of segmented gate trenches extend in a first direction in the semiconductor layer structure. The segmented gate trenches include respective gate trench segments that are spaced apart from each other in the first direction with intervening regions of the semiconductor layer structure therebetween. Related devices and fabrication methods are also discussed.

A MOS transistor, in particular a vertical channel transistor, includes a semiconductor body housing a body region, a source region, a drain electrode and gate electrodes. The gate electrodes extend in corresponding recesses which are symmetrical with respect to an axis of symmetry of the semiconductor body. The transistor also has spacers which are also symmetrical with respect to the axis of symmetry. A source electrode extends in electrical contact with the source region at a surface portion of the semiconductor body surrounded by the spacers and is in particular adjacent to the spacers. During manufacture the spacers are used to form in an auto-aligning way the source electrode which is symmetrical with respect to the axis of symmetry and equidistant from the gate electrodes.

A semiconductor device including: a first S/D arrangement including a silicide-sandwiched portion of a corresponding active region having a silicide-sandwiched configuration, a first portion of a corresponding metal-to-drain/source (MD) contact structure, a first via-to-MD (VD) structure, and a first buried via-to-source/drain (BVD) structure; a gate structure over a channel portion of the corresponding active region; and a second S/D arrangement including a first doped portion of the corresponding active region; and at least one of the following: an upper contact arrangement including a first silicide layer over the first doped portion, a second portion of the corresponding MD contact structure; and a second VD structure; or a lower contact arrangement including a second silicide layer under the first doped portion, and a second BVD structure.

A power converter circuit includes a switch including a field effect transistor, the field effect transistor being a wide bandgap field effect transistor and being configured to maintain an on operational state responsive to a maintenance signal received through a gate terminal, a current sensing circuit that is configured to estimate a drain terminal current of the field effect transistor responsive to a voltage between the gate terminal of the field effect transistor and a source terminal of the field effect transistor, and a gate driving circuit that is configured to generate the maintenance signal responsive to the estimate of the drain terminal current.

A method of manufacturing a semiconductor device includes: forming a trench in a first side of a semiconductor layer, the semiconductor layer including a drift zone of a first conductivity; forming a drain region of the first conductivity type in the first side of the semiconductor layer and laterally adjoining the drift zone; forming a body region of a second conductivity type opposite the first conductivity type and laterally adjoining the drift zone at a side of the drift zone opposite the drain region; and forming source regions of the first conductivity type and body contact regions of the second conductivity type in a sidewall of the trench and arranged in an alternating manner along a length of the trench, using a dopant diffusion process which includes diffusing dopants of both conductivity types from oppositely-doped dopant source layers which are in contact with different regions of the sidewall.

Disclosed are method and an apparatus for analysis of an interface state of a MIS-HEMT device. By means of establishing an equivalent model of MIS-HEMT(s) that includes equivalent circuits representing a dielectric layer, a barrier layer and a channel layer, plotting a group of a capacitance-frequency function curve and a conductance-frequency function curve that can be best fitted to the measured capacitance-frequency scatter diagram and the measured conductance-frequency scatter diagram via the equivalent model, taking such best-fitted group as the fitted function curve group, and calculating parameters about the interface state of MIS-HEMT(s) according to the group of assigned values corresponding to the fitted function curve group, the parameters of the analyzed interface state can be more accurate since the fitted frequency function curve group can, with the aid of the equivalent model, simultaneously fit the measured capacitance-frequency scatter diagram and the measured conductance-frequency scatter diagram.

Provided are a semi-conductor structure and a manufacturing method thereof. The semi-conductor structure includes: a substrate, a heterojunction, a P-type ion doped layer and a gate insulation layer disposed from bottom to top, wherein the heterojunction includes a source region, a drain region and a gate region; the P-type ion doped layer in the gate region includes an activated region and non-activated regions, P-type doping ions in the activated region are activated, and P-type doping ions in the non-activated regions are passivated; the non-activated regions include at least two regions which are spaced apart in a direction perpendicular to a connection line of the source region and the drain region; the gate insulation layer is located on the non-activated region to expose the activated region.

A high electron mobility transistor (HEMT) includes a carrier transit layer, a carrier supply layer, a main gate, a control gate, a source electrode and a drain electrode. The carrier transit layer is on a substrate. The carrier supply layer is on the carrier transit layer. The main gate and the control gate are on the carrier supply layer. A fluoride ion doped region is formed right below the main gate in the carrier supply layer. The source electrode and the drain electrode are at two opposite sides of the main gate and the control gate, wherein the source electrode is electrically connected to the control gate by a metal interconnect. The present invention also provides a method of forming a high electron mobility transistor (HEMT).

A semiconductor device includes a III-V compound semiconductor layer, a III-V compound barrier layer, a gate trench, and a p-type doped III-V compound layer. The III-V compound barrier layer is disposed on the III-V compound semiconductor layer. The gate trench is disposed in the III-V compound barrier layer. The p-type doped III-V compound layer is disposed in the gate trench, and a top surface of the p-type doped III-V compound layer and a top surface of the III-V compound barrier layer are substantially coplanar.

The present disclosure describes a semiconductor device that includes a transistor. The transistor includes a source/drain region that includes a front surface and a back surface opposite to the front surface. The transistor includes a salicide region on the back surface and a channel region in contact with the source/drain region. The channel region has a front surface co-planar with the front surface of the source/drain region. The transistor further includes a gate structure disposed on a front surface of the channel region. The semiconductor device also includes a backside contact structure that includes a conductive contact in contact with the salicide region and a liner layer surrounding the conductive contact.