A semiconductor device includes an anode doping region of a diode structure arranged in a semiconductor substrate. The anode doping region has a first conductivity type. The semiconductor device further includes a second conductivity type contact doping region having a second conductivity type. The second conductivity type contact doping region is arranged at a surface of the semiconductor substrate and surrounded in the semiconductor substrate by the anode doping region. The anode doping region includes a buried non-depletable portion. At least part of the buried non-depletable portion is located below the second conductivity type contact doping region in the semiconductor substrate.

The invention provides a manufacturing method of a semiconductor structure, the method includes providing a substrate, forming two shallow trench isolation structures in the substrate. A first region, a second region and a third region are defined between the two shallow trench isolation structures, and the second region is located between the first region and the third region. Next, an oxide layer is formed in the first region, the second region and the third region, and the oxide layer directly contacts the two shallow trench isolation structures. The oxide layer in the second region is then removed, and another oxide layer is formed in the first region, the second region and the third region, so that a thick oxide layer is formed in the first and third regions, and a thin oxide layer is formed in the second region.

A wafer includes a semiconductor substrate. The semiconductor substrate includes a plurality of first doped regions and a plurality of second doped regions. The first doped regions and the second doped regions are located on a first surface of the semiconductor substrate. The second doped regions contact the first doped regions. The first doped regions and the second doped regions are alternately arranged. Both of the first doped regions and the second doped regions include a plurality of N-type dopants. The doping concentration of the N-type dopants in each of the first doped regions is not greater than the doping concentration of the N-type dopants in each of the second doped regions.

A MOSFET includes a semiconductor body having a first side, a drift region, a body region forming a first pn-junction with the drift region, a source region forming a second pn-junction with the body region, in a vertical cross-section, a dielectric structure on the first side and having an upper side; a first gate electrode, a second gate electrode, a contact trench between the first and second gate electrodes, extending through the dielectric structure to the source region, in a horizontal direction a width of the contact trench has, in a first plane, a first value, and, in a second plane, a second value which is at most about 2.5 times the first value, and a first contact structure arranged on the dielectric structure having a through contact portion arranged in the contact trench, and in Ohmic contact with the source region.

A method of fabricating a device includes providing a fin element in a device region and forming a dummy gate over the fin element. In some embodiments, the method further includes forming a source/drain feature within a source/drain region adjacent to the dummy gate. In some cases, the source/drain feature includes a bottom region and a top region contacting the bottom region at an interface interposing the top and bottom regions. In some embodiments, the method further includes performing a plurality of dopant implants into the source/drain feature. In some examples, the plurality of dopant implants includes implantation of a first dopant within the bottom region and implantation of a second dopant within the top region. In some embodiments, the first dopant has a first graded doping profile within the bottom region, and the second dopant has a second graded doping profile within the top region.

The invention provides a semiconductor structure, the semiconductor structure includes a substrate, two shallow trench isolation structures are located in the substrate, a first region, a second region and a third region are defined between the two shallow trench isolation structures, the second region is located between the first region and the third region. Two thick oxide layers are respectively located in the first region and the third region and directly contact the two shallow trench isolation structures respectively, and a thin oxide layer is located in the second region, the thickness of the thick oxide layer in the first region is greater than that of the thin oxide layer in the second region.

A method of forming a semiconductor arrangement includes forming a gate dielectric layer over a semiconductor layer. A gate electrode layer is formed over the gate dielectric layer. A first gate mask is formed over the gate electrode layer. The gate electrode layer is etched using the first gate mask as an etch template to form a first gate electrode. A first dopant is implanted into the semiconductor layer using the first gate mask and the first gate electrode as an implantation template to form a first doped region in the semiconductor layer.

A channel stop and well dopant migration control implant (e.g., of argon) can be used in the fabrication of a transistor (e.g., PMOS), either around the time of threshold voltage adjust and well implants prior to gate formation, or as a through-gate implant around the time of source/drain extension implants. With its implant depth targeted about at or less than the peak of the concentration of the dopant used for well and channel stop implants (e.g., phosphorus) and away from the substrate surface, the migration control implant suppresses the diffusion of the well and channel stop dopant to the surface region, a more retrograde concentration profile is achieved, and inter-transistor threshold voltage mismatch is improved without other side effects. A compensating through-gate threshold voltage adjust implant (e.g., of arsenic) or a threshold voltage adjust implant of increased dose can increase the magnitude of the threshold voltage to a desired level.

After the various regions of a vertical power device are formed in or on the top surface of an n-type wafer, the wafer is thinned, such as by grinding. A drift layer may be n-type, and various n-type regions and p-type regions in the top surface contact a top metal electrode. A blanket dopant implant through the bottom surface of the thinned wafer is performed to form an n− buffer layer and a bottom p+ emitter layer. Energetic particles are injected through the bottom surface to intentionally damage the crystalline structure. A wet etch is performed, which etches the damaged crystal at a much greater rate, so some areas of the n− buffer layer are exposed. The bottom surface is metallized. The areas where the metal contacts the n− buffer layer form cathodes of an anti-parallel diode for conducting reverse voltages, such as voltage spikes from inductive loads.

Provided is a manufacturing method for a semiconductor device including forming a first electrode layer on a front surface of a wafer, implanting, into an outer peripheral region of the front surface of the wafer, a heavy ion of an element in third and subsequent rows of a periodic table, forming an oxide film in the outer peripheral region into which the heavy ion has been implanted, and forming a second electrode layer on the first electrode layer by plating. A dose of the heavy ion may be 1E15 cm.sup.−2 or more. A depth of an implantation range of the heavy ion into the wafer may be 0.02 μm or more. The heavy ion may be an As ion, a P ion, or an Ar ion.