A charge pump circuit includes a voltage input port, a voltage output port, a plurality of charge pump units cascaded between the voltage input port and the voltage output port, a clock signal source, and N clock delay elements. The clock signal source generates a main clock signal and the N clock delay elements generate clock signals received by the charge pump units by delaying the main clock signal. The main clock signal received by the first charge pump unit has a rising edge leading a rising edge of the last clock signal received by the last charge pump unit, and a falling edge lagging the rising edge of the last clock signal. Each of the charge pump units includes two sets of inverters with delay elements for generating two complementary clock signals.

A lateral double-diffused metal-oxide-semiconductor field effect transistor includes a silicon semiconductor structure, first and second gate structures, and a trench dielectric layer. The first and second gate structures are disposed on the silicon semiconductor structure and separated from each other in a lateral direction. The trench dielectric layer is disposed in a trench in the silicon semiconductor structure and extends at least partially under each of the first and second gate structures in a thickness direction orthogonal to the lateral direction.

There are disclosed herein various implementations of a semiconductor structure and method. The semiconductor structure comprises a substrate, a transition body over the substrate, and a group III-V intermediate body having a bottom surface over the transition body. The semiconductor structure also includes a group III-V device layer over a top surface of the group III-V intermediate body. The group III-V intermediate body has a continuously reduced impurity concentration wherein a higher impurity concentration at the bottom surface is continuously reduced to a lower impurity concentration at the top surface.

An integrated circuit and method having an extended drain MOS transistor with a buried drift region, a drain diffused link, a channel diffused link, and an isolation link which electrically isolated the source, where the isolation diffused link is formed by implanting through segmented areas to dilute the doping to less than two-thirds the doping in the drain diffused link.

A semiconductor device includes an element portion and a gate pad portion on the same wide gap semiconductor substrate. The element portion includes a first trench structure having a plurality of first protective trenches and first buried layers formed deeper than gate trenches. The gate pad portion includes a second trench structure having a plurality of second protective trenches and second buried layers. The second trench structure is either one of a structure where the second trench structure includes: a p-type second semiconductor region and a second buried layer made of a conductor or a structure where the second trench structure includes a second buried layer formed of a metal layer which forms a Schottky contact. The second buried layer is electrically connected with the source electrode layer.

A semiconductor apparatus includes: a gate electrode in a trench and facing a p type base region with a gate insulating film interposed therebetween on a portion of a side wall; a shield electrode in the trench and between the gate electrode and a bottom of the trench; an electric insulating region in the trench, the electric insulating region extending between the gate electrode and the shield electrode, and further extending along the side wall and the bottom of the trench to separate the shield electrode from the side wall and the bottom; a source electrode electrically connected to an n.sup.+ type source region and the shield electrode. The shield electrode has high resistance regions at positions where the high resistance regions face the side walls of the trench, and a low resistance region at a position where the low resistance region is sandwiched between the high resistance regions.

Provided is a semiconductor apparatus includes: a gate electrode disposed inside a trench and opposedly facing a p type base region with a gate insulating film interposed therebetween on a portion of a side wall; a shield electrode disposed inside the trench and positioned between the gate electrode and a bottom of the trench; an electric insulating region disposed inside the trench, the electric insulating region expanding between the gate electrode and the shield electrode, and further expanding along the side wall and the bottom of the trench so as to separate the shield electrode from the side wall and the bottom; a source electrode electrically connected to an n.sup.+ type source region and the shield electrode, wherein the shield electrode has a high resistance region positioned on an n.sup.+ drain region side, and a low resistance region positioned on a gate electrode side.

An electrostatic protection includes a buried layer having an outer region and an inner region which are heavily doped regions of a first conductivity type. The inner region is surrounded by an undoped or lightly doped ring region. The ring region is surrounded by the outer region. The device further includes a semiconductor region over the buried layer, a first well of the first conductivity type in the semiconductor region, a first transistor in the semiconductor region, and a second transistor in the semiconductor region. The first well forms a collector of the first transistor and a collector of the second transistor.

Semiconductor devices includes a thin epitaxial layer (nanotube) formed on sidewalls of mesas formed in a semiconductor layer. In one embodiment, a semiconductor device includes a first semiconductor layer, a second semiconductor layer formed thereon and of the opposite conductivity type, and a first epitaxial layer formed on mesas of the second semiconductor layer. An electric field along a length of the first epitaxial layer is uniformly distributed.

The subject matter disclosed herein relates to semiconductor power devices, such as silicon carbide (SiC) power devices. In particular, the subject matter disclosed herein relates to shielding regions in the form of channel region extensions for that reduce the electric field present between the well regions of neighboring device cells of a semiconductor device under reverse bias. The disclosed channel region extensions have the same conductivity-type as the channel region and extend outwardly from the channel region and into the JFET region of a first device cell such that a distance between the channel region extension and a region of a neighboring device cell having the same conductivity type is less than or equal to the parallel JFET width. The disclosed shielding regions enable superior performance relative to a conventional stripe device of comparable dimensions, while still providing similar reliability (e.g., long-term, high-temperature stability at reverse bias).