An insulated gate bipolar transistor and a fabrication method therefor, wherein the fabrication method for the insulated gate bipolar transistor comprises the following steps: implanting hydrogen ions, arsenic ions, or nitrogen ions into a substrate from a back surface of the insulated gate bipolar transistor so as to form an n-type heavily doped layer (202) of a reverse conduction diode, the reverse conduction diode being a reverse conduction diode built into the insulated gate bipolar transistor. The described fabrication method and the obtained insulated gate bipolar transistor from a recombination center in an n+ junction of the reverse conduction diode, thereby accelerating the reverse recovery speed of the built-in reverse conduction diode, shortening the reverse recovery time thereof, and improving the performance of the insulated gate bipolar transistor.

The present disclosure relates to semiconductor structures and, more particularly, to a lateral bipolar transistor and methods of manufacture. The structure includes: an extrinsic base region; an emitter region on a first side of the extrinsic base region; a collector region on a second side of the extrinsic base region; and a gate structure comprising a gate oxide and a gate control in a same channel region as the extrinsic base region.

In one aspect, a method of fabricating a transistor includes depositing a first epitaxial layer; depositing a second epitaxial layer on the first epitaxial layer; forming a single termination trench in the second epitaxial layer; and filling the termination trench with a dielectric. A depth of the termination trench is greater than 10 microns. In another aspect, a transistor includes a first epitaxial layer; a second epitaxial layer on the first epitaxial layer; and a single termination trench in the second epitaxial layer. The termination trench is greater than 10 microns and is filled with a dielectric.

We herein describe a method of manufacturing a semiconductor device having one or more trenches with an insulation layer. The one or more trenches with an insulation layer are manufactured using the steps of performing an etching process to form the one or more trenches, forming a first insulation layer on a lower surface and sidewalls of the one or more trenches, depositing a hydrophilic layer over the first insulation layer, depositing a photoresist material in the one or more trenches, wherein depositing a photoresist material comprises exposing the hydrophilic layer on an upper region of a first side of the one or more trenches, performing a wet etch process to etch the insulation layer on the sidewall of the first side of the one or more trenches to a predetermined distance below a surface of the photoresist material, removing the photoresist material, removing the hydrophilic layer, and after performing the wet etch process, removing the photoresist material, and removing the hydrophilic layer, and forming a second insulation layer on the sidewall of the first side of the one or more trenches.

An IGBT and a manufacturing method therefor, wherein a target region in the IGBT is doped with first ions; the target region comprises at least one of a P-type substrate (11), a P-type well region (13), and a P-type source region (14); and the diffusion coefficient of the first ions is greater than the diffusion coefficients of boron ions. A PN junction formed by means of the present invention is a gradual junction, thereby improving breakdown voltage, shortening turn-off time, and improving anti-latch capability.

A power device which is formed on a semiconductor substrate includes: a lateral insulated gate bipolar transistor (LIGBT), a PN diode and a clamp diode. The PN diode is connected in parallel to the LIGBT. The clamp diode has a clamp forward terminal and a clamp reverse terminal, which are electrically connected to a drain and a gate of the LIGBT, to clamp a gate voltage applied to the gate not to be higher than a predetermined voltage threshold.

A power semiconductor device has a semiconductor body configured to conduct a load current in parallel to an extension direction between first and second load terminals of the power semiconductor device. The semiconductor body includes a doped contact region electrically connected to the second load terminal, a doped drift region having a dopant concentration that is smaller than a dopant concentration of the contact region, and an epitaxially grown doped transition region separated from the second load terminal by the contact region and that couples the contact region to the drift region. An upper subregion of the transition region is in contact with the drift region, and a lower subregion of the transition region is in contact with the contact region. The transition region has a dopant concentration of at least 0.5*10.sup.15 cm.sup.−3 for at least 5% of the total extension of the transition region in the extension direction.

A method of fabricating a transistor includes doping non-overlapping first, second, and third wells in a silicon layer of a substrate. The substrate, second and third wells have a first type of conductivity and the first well and silicon layer have a second type of conductivity. First and second insulating layers are thermally grown over the second well between the first well and the third well, and over the third well, respectively. A gate stack is formed over the first insulating layer and the third well. A first source region having the second type of conductivity is formed in the third well. A gate spacer is formed, a fourth well having the first type of conductivity is doped in the third well between the second insulating layer and the gate spacer, a second source region is formed over the fourth well, and a drain is formed in the first well.

To realize a highly reliable IGBT that suppresses the bipolar degradation by preventing the occurrence of a defect on a boundary between a contact region and a silicide layer. As a means to realize the above, a semiconductor device includes: a collector region that is formed on a lower surface of a semiconductor substrate and forms an IGBT; and a collector electrode that is formed on a lower surface of the collector region via a silicide layer. The collector region and the silicide layer contains aluminum, first metal being more easily bondable to silicon than aluminum, and second metal being more easily bondable to carbon than aluminum.

The present disclosure relates to semiconductor structures and, more particularly, to bipolar transistors and methods of manufacture. The structure includes: an intrinsic base region; an emitter region above the intrinsic base region; a collector region under the intrinsic base region; and an extrinsic base region comprising metal material, and which surrounds the intrinsic base region and the emitter region.