A semiconductor device includes a substrate having a first conductivity type and including a cell region and a termination region. A trench is disposed in the substrate and located in the cell region, and a gate electrode disposed in the trench. A shielding doped region having a second conductivity type is disposed in the substrate and directly below the trench. A buried guard ring having the second conductivity type is disposed in the substrate and located in the termination region. The buried guard ring and the shielding doped region are disposed at the same depth in the substrate. In addition, a junction termination extension structure having the second conductivity type is disposed in the substrate, located directly above and separated from the buried guard ring.

A switched-mode power supply includes a power semiconductor device that includes a semiconductor body comprising transistor cells and a drift zone between a drain layer and the transistor cells, the transistor cells comprising source zones, wherein the device exhibits a first output charge gradient when a voltage between the drain layer and the source zones of the transistor cells increases from a depletion voltage of the semiconductor device to a maximum drain/source voltage of the semiconductor device, wherein the device exhibits a second output charge gradient when a voltage between the drain layer and the source zones of the semiconductor device decreases from the maximum drain/source voltage to the depletion voltage of the semiconductor device, and wherein the semiconductor device is configured such that the first output charge gradient deviates by less than 5% from the second output charge gradient.

The present disclosure relates to a power semiconductor device (100) comprising a silicon carbide semiconductor. SiC. structure (110) comprising a SiC epilayer (112), at least one ohmic contact (120) formed on a first main surface (114) of the SiC structure (110), and at least Schottky barrier contact (130) formed on a second main surface (116) of the SiC structure (110). The at least one Schottky barrier contact (130) comprises a metal layer (136) and a carbon group interlayer (134) arranged between the metal layer (136) and the second main surface (116) of the SiC structure (110). 15 The present disclosure relates to a Schottky barrier diode (400). a vertical field effect transistor, such as a power MOSFET (500), and a method for manufacturing a power semiconductor device (100).

A semiconductor device includes: a semiconductor substrate; a drift zone of a first conductivity type in the semiconductor substrate; an array of interconnected gate trenches extending from a first surface of the semiconductor substrate into the drift zone; a plurality of semiconductor mesas delimited by the array of interconnected gate trenches; a plurality of needle-shaped field plate trenches extending from the first surface into the plurality of semiconductor mesas; in the plurality of semiconductor mesas, a source region of the first conductivity type and a body region of a second conductivity type separating the source region from the drift zone; and a current spreading region of the first conductivity type at the bottom of the gate trenches and having a higher average doping concentration than the drift zone. Methods of producing the semiconductor device are also described.

An embodiment semiconductor device includes a conductive region extending in a first direction and a second direction intersecting the first direction and stacked in a third direction intersecting the first direction and the second direction and a termination region at an end of the conductive region in the first direction, wherein the termination region includes an n+ type substrate, an n type layer disposed on an upper surface of the n+ type substrate and having a plurality of first trenches opening upward in the third direction, and a lower gate runner covering the plurality of first trenches and disposed on an upper surface of the n type layer.

A semiconductor device includes an active region, which is a region where main current flows, an edge termination region surrounding the active region, a step surface surrounding the edge termination region, and a dicing line surrounding the step surface. The active region has a first pn junction of a first semiconductor region and a second semiconductor layer and a second pn junction of an outer peripheral region and the second semiconductor layer. The step surface is provided with a first protective film for shielding light generated as forward current flows through the first and second pn junctions in the active region.

A semiconductor device includes a semiconductor substrate having an element region and a terminal region located around the element region. The terminal region includes multiple guard rings and multiple first diffusion regions. When the semiconductor substrate is viewed in a plan view, one of the first diffusion regions is arranged correspondingly to one of the guard rings, and each of the guard rings is located in corresponding one of the first diffusion regions. A width of each of the first diffusion regions is larger than a width of corresponding one of the guard rings.

A semiconductor device with an active transistor cell comprising a p-doped first and second base layers, surrounding an n type source region, the device further comprising a plurality of first gate electrodes embedded in trench recesses, has additional fortifying p-doped layers embedding the opposite ends of the trench recesses. The additional fortifying layers do not affect the active cell design in terms of cell pitch i.e., the design rules for transistor cell spacing, or hole drainage between the transistor cells, but reduce the gate-collector parasitic capacitance of the semiconductor, hence leading to optimum low conduction and switching losses. To further reduce the gate-collector capacitance, the trench recesses embedding the first gate electrodes can be formed with thicker insulating layers in regions that do not abut the first base layers, so as not to negatively impact the value of the threshold voltage.

In a semiconductor device, a source region is made of an epitaxial layer so as to reduce variation in thickness of a base region and variation in a threshold value. Outside of a cell part, a side surface of a gate trench is inclined relative to a normal direction to a main surface of a substrate, as compared with a side surface of a gate trench in the cell part that is provided by the epitaxial layer of the source region being in contact with the base region.

A termination region of an IGBT is described, in which surface p-rings are combined with oxide/polysilicon-filled trenches, buried p-rings and surface field plates, so as to obtain an improved distribution of potential field lines in the termination region. The combination of surface ring termination and deep ring termination offers a significant reduction in the amount silicon area which is required for the termination region.