A diode is formed by a polycrystalline silicon bar which includes a first doped region with a first conductivity type, a second doped region with a second conductivity type and an intrinsic region between the first and second doped regions. A conductive layer extends parallel to the polycrystalline silicon bar and separated from the polycrystalline silicon bar by a dielectric layer. The conductive layer is configured to be biased by a bias voltage.

A semiconductor device includes first and second pads separated from each other, first and second test elements connected to the first and second pads and connected to each other in parallel between the first and second pads, a first diode connected to the first test element in series, and a second diode connected to the second test element in series.

A method for manufacturing a three-dimensional semiconductor diode device comprises providing a substrate comprising a silicon substrate and a first oxide layer formed on the silicon substrate; depositing a plurality of stacked structures on the substrate, each of the stacked structures comprising a dielectric layer and a conductive layer; etching the stacked structures through a photoresist layer which is patterned to form at least one trench in the stacked structures, a bottom of the trench exposing the first oxide layer; depositing a second oxide layer on the stacked structures and the trench; depositing a high-resistance layer on the second oxide layer, the high-resistance layer comprising a first polycrystalline silicon layer and a first conductive compound layer; and depositing a low-resistance layer on the high-resistance layer, the low-resistance layer comprising a second polycrystalline silicon layer and a second conductive compound layer.

A number of monolithic diode limiter semiconductor structures are described. The diode limiters can include a hybrid arrangement of diodes with different intrinsic regions, all formed over the same semiconductor substrate. In one example, a method of manufacture of a monolithic diode limiter includes providing an N-type semiconductor substrate, providing an intrinsic layer on the N-type semiconductor substrate, implanting a first P-type region to a first depth into the intrinsic layer, implanting a second P-type region to a second depth into the intrinsic layer, and forming at least one passive circuit element over the intrinsic layer. The method can also include forming an insulating layer on the intrinsic layer, forming a first opening in the insulating layer, and forming a second opening in the insulating layer. The method can also include implanting the first P-type region through the first opening and implanting the second P-type region through the second opening.

A method of processing a power diode includes: creating an anode region and a drift region in a semiconductor body; and forming, by a single ion implantation processing step, each of an anode contact zone and an anode damage zone in the anode region. Power diodes manufactured by the method are also described.

A semiconductor device including a protected element, a contact region, wiring, and a channel stopper region. The protected element is configured including a p-n junction diode between an anode region and a cathode region, and is arranged in an active layer of a substrate. The periphery of the diode is surrounded by an element isolation region. The contact region is arranged at a portion on a main face of the anode region, and is set with a same conductivity type as the anode region, and set with a higher impurity concentration than the anode region. The wiring is arranged over the diode. One end portion of the wiring is connected to the contact region and another end portion extends over a passivation film. The channel stopper region is arranged at a portion on the main face of the anode region under the wiring between the contact region and the element isolation region, and is set with an opposite conductivity type to the contact region.

A trench in a semiconductor substrate is lined with a first insulation layer. A hard mask layer deposited on the first insulation layer is used to control performance of an etch that selectively removes a first portion of the first insulating layer from an upper trench portion while leaving a second portion of first insulating layer in a lower trench portion. After removing the hard mask layer, an upper portion of the trench is lined with a second insulation layer. An opening in the trench that includes a lower open portion delimited by the second portion of first insulating layer in the lower trench portion and an upper open portion delimited by the second insulation layer at the upper trench portion, is then filled by a single deposition of polysilicon material forming a unitary gate/field plate conductor of a field effect rectifier diode.

A germanium based avalanche photo-diode device and method of manufacture thereof. The device including: a silicon substrate; a lower doped silicon region, positioned above the substrate; a silicon multiplication region, positioned above the lower doped silicon region; an intermediate doped silicon region, positioned above the silicon multiplication region; an un-doped germanium absorption region, position above the intermediate doped silicon region; an upper doped germanium region, positioned above the un-doped germanium absorption region; and an input silicon waveguide; wherein: the un-doped germanium absorption region and the upper doped germanium region form a germanium waveguide which is coupled to the input waveguide, and the device also includes a first electrode and a second electrode, and the first electrode extends laterally to contact the lower doped silicon region and the second electrode extends laterally to contact the upper doped germanium region.

A vertical power semiconductor device is described. The vertical power semiconductor device includes a semiconductor body having a first main surface and a second main surface opposite to the first main surface. A thickness of the semiconductor body between the first main surface and the second main surface ranges from 40 μm to 200 μm. Active device elements are formed in the semiconductor body at the first main surface. Edge termination elements at least partly surround the active device elements at the first main surface. A diffusion region extends into the semiconductor body from the second main surface. A doping concentration profile of the diffusion region decreases from a peak concentration Ns at the second main surface to a concentration Ns/e, e being Euler's number, over a vertical distance ranging from 1 μm to 5 μm.

A semiconductor device and a method of manufacturing a semiconductor are provided. In an embodiment, a first trench is formed in a silicon carbide layer. A second trench is formed in the silicon carbide layer to define a mesa in the silicon carbide layer between the first trench and the second trench. A first doped semiconductor material is formed in the first trench and a second doped semiconductor material is formed in the second trench. A third doped semiconductor material is formed over the mesa to define a heterojunction at an interface between the third doped semiconductor material and the mesa.