A bidirectional Metal-Oxide-Semiconductor (MOS) device, including a P-type substrate, and an active region. The active region includes a drift region, a first MOS structure and a second MOS structure; the first MOS structure includes a first P-type body region, a first P+ contact region, a first N+ source region, a first metal electrode, and a first gate structure; the second MOS structure includes a second P-type body region, a second P+ contact region, a second N+ source region, a second metal electrode, and a second gate structure; and the drift region includes a dielectric slot, a first N-type layer, a second N-type layer, and an N-type region. The active region is disposed on the upper surface of the P-type substrate. The first MOS structure and the second MOS structure are symmetrically disposed on two ends of the upper layer of the drift region.

A silicon carbide semiconductor device includes an electric field relaxation layer disposed in a drift layer. The electric field relaxation layer includes a first region having a second conductivity type and disposed at a position deeper than trenches, and a second region having the second conductivity type and disposed between the adjacent trenches to be away from a side surface of each of the adjacent trenches. Each of the first region and the second region is made of an ion implantation layer. The electric field relaxation layer further includes a double implantation region in which the first region and the second region overlap with each other, and the electric field relaxation layer has a peak of a second conductivity type impurity concentration in the double implantation region.

A semiconductor device includes a substrate having a first conductivity type, a high-voltage well having a second conductivity type and disposed in the substrate, a high-voltage doped region having the first conductivity type and disposed in the high-voltage well, a drain region disposed in the high-voltage well and spaced apart from the high-voltage doped region, a source region disposed in the high-voltage doped region, a first gate structure disposed above a first side portion of the high-voltage doped region between the source region and the drain region, and a second gate structure disposed above a second and opposite side portion of the high-voltage doped region.

This invention discloses an insulated gate bipolar transistor (IGBT) device formed in a semiconductor substrate. The IGBT device has a split-shielded trench gate that includes an upper gate segment and a lower shield segment. The IGBT device may further include a dummy trench filled with a dielectric layer disposed at a distance away from the split-shielded trench gate. The IGBT device further includes a body region extended between the split-shielded trench gate and the dummy trench encompassing a source region surrounding the split-shielded trench gate near a top surface of the semiconductor substrate. The IGBT device further includes a heavily doped N region disposed below the body region and above a source-dopant drift region above a bottom body-dopant collector region at a bottom surface of the semiconductor substrate. In an alternative embodiment, the IGBT may include a planar gate with a trench shield electrode.

A field stop insulated gate bipolar transistor (IGBT) fabricated without back-side laser dopant activation or any process temperatures over 450 C. after fabrication of front-side IGBT structures provides activated injection regions with controlled dopant concentrations. Injection regions may be formed on or in a substrate by epitaxial growth or ion implants and diffusion before growth of N field stop and drift layers and front-side fabrication of IGBT active cells. Back-side material removal can expose the injection region(s) for electrical connection to back-side metal. Alternatively, after front-side fabrication of IGBT active cells, back-side material removal can expose the field stop layer (or injection regions) and sputtering using a silicon target with a well-controlled doping concentration can form hole or electron injection regions with well-controlled doping concentration.

Various methods for manufacturing semiconductor structures are provided. An embodiment method includes forming a first patterned hard mask and epitaxial layer on a semiconductor substrate, and forming a first doped region in the epitaxial layer by performing a first implantation through the first patterned hard mask. A second doped region is formed in the epitaxial layer by performing a second implantation through the first patterned hard mask, with the first doped region at least partially overlapping the second doped region. A second patterned hard mask is formed, which surrounds the first patterned hard mask and covers at least a portion of the first doped region. A third doped region is formed in the epitaxial layer by performing a third implantation through the first patterned hard mask and the second patterned hard mask.

A method includes: providing a layer of porous silicon carbide supported by a silicon carbide substrate; providing a layer of epitaxial silicon carbide on the layer of porous silicon carbide; forming semiconductor devices in the layer of epitaxial silicon carbide; and separating the silicon carbide substrate from the layer of epitaxial silicon carbide at the layer of porous silicon carbide. The layer of porous silicon carbide includes dopants defining a resistivity of the layer of porous silicon carbide. The resistivity of the layer of porous silicon carbide is different from a resistivity of the silicon carbide substrate. Additional methods are described.

The present application discloses an SiC MOSFET device, including an SiC epitaxial layer in which a trench gate is formed, wherein a first bottom doped region is formed below a bottom surface of a gate trench, a second deep doped region with spacing from the gate trench is formed in the SiC epitaxial layer, the first bottom doped region is connected to a source so that voltage borne by a gate dielectric layer on the bottom surface of the gate trench is determined by gate-source voltage; the second deep doped region extends downward from a top surface of the SiC epitaxial layer, and a bottom surface of the second deep doped region is located below a bottom surface of the first bottom doped region; a top of the second deep doped region is connected to the source. The present application further discloses a method for manufacturing an SiC MOSFET device.

A source-body self-aligned method of a VDMOSFET is provided. A pad layer and an unoxidized material layer are sequentially formed on an epitaxial layer on a semiconductor substrate. A lithography process is then carried out for patterning. Later, a thermal oxidation process is employed such that the unoxidized material layer is oxidized to form oxidation layers. Then, a source ion implantation process is performed, and a wet etching is used to remove the oxidation layers before successively employing a body ion implantation process. By using the process method disclosed in the present invention, it achieves to form the source region and the body region which are self-aligned. Meanwhile, since process complexity of the invention is relatively low, process uniformity and process cost can be optimally controlled. In addition, the invention achieves to reduce channel length and on-resistance, thereby enhancing the reliability effectively.

An electrostatic discharge (ESD) protection device includes a semiconductor substrate, a base region in the semiconductor substrate and having a first conductivity type, an emitter region in the base region and having a second conductivity type, a collector region in the semiconductor substrate, spaced from the base region, and having the second conductivity type, a breakdown trigger region having the second conductivity type, disposed laterally between the base region and the collector region to define a junction across which breakdown occurs to trigger the ESD protection device to shunt ESD discharge current, and a gate structure supported by the semiconductor substrate over the breakdown trigger region and electrically tied to the base region and the emitter region. The lateral width of the breakdown trigger region is configured to establish a voltage level at which the breakdown occurs.