A semiconductor device includes a backside contact and a substrate. An epitaxial field stop region may be formed on the substrate with a graded doping profile that decreases with distance away from the substrate, and an epitaxial drift region may be formed adjacent to the epitaxial field stop region. A frontside device may be formed on the epitaxial drift region.

A semiconductor device includes: an n type semiconductor layer including an active region and an inactive region; an element structure formed in the active region and including at least an active side p type layer to form pn junction with n type portion of the n type semiconductor layer; an inactive side p type layer formed in the inactive region and forming pn junction with the n type portion of the n type semiconductor layer; a first electrode electrically connected to the active side p type layer in a front surface of the n type semiconductor layer; a second electrode electrically connected to the n type portion of the n type semiconductor layer in a rear surface of the n type semiconductor layer; and a crystal defect region formed in both the active region and the inactive region and having different depths in the active region and the inactive region.

An insulated gate bipolar transistor and a preparation method thereof, and an electronic device. The insulated gate bipolar transistor includes: a drift region; an electrode structure on one side of the drift region; and an electric field stop layer arranged on one side of the drift region away from the electrode structure. The electric field stop layer includes a first sublayer and a second sublayer laminated together. The first sublayer is arranged close to the drift region. A junction depth of the first sublayer is greater than a junction depth of the second sublayer. A peak value of a doping concentration of the first sublayer is less than a peak value of a doping concentration of the second sublayer. A slope of a doping concentration curve of the first sublayer is less than a slope of a doping concentration curve of the second sublayer.

A power semiconductor device includes an active region and an edge termination region surrounding the active region. A field plate structure arranged around the active region includes at least one electrically conductive track electrically connected to a first potential of a first load terminal at a first joint and, at a second joint, electrically connected to a second potential of a second load terminal. The track forms at least n crossings, wherein n is greater 5, with a straight virtual line that extends from the active region towards an edge of the edge termination region. The difference in potential between adjacent two crossings increases in at least 50% of the length of the virtual line, and/or the difference in potential within, with respect to the active region, the first 20% of the length of virtual line is less than 10% of the total difference in potential along the virtual line.

Disclosed herein are methods for backside wafer dopant activation using a high-temperature ion implant. In some embodiments, a method may include forming a semiconductor device atop a first main side of a substrate, and performing a high-temperature ion implant to a second main side of the substrate, wherein the first main side of the substrate is opposite the second main side of the substrate. The method may further include performing a second ion implant to the second main side of the substrate to form a collector layer.

Disclosed herein are methods for backside wafer dopant activation using a low-temperature ion implant. In some embodiments, a method may include forming a semiconductor device atop a first main side of a substrate, and performing a low-temperature ion implant to a second main side of the substrate, wherein the first main side of the substrate is opposite the second main side of the substrate. The method may further include performing a second ion implant to the second main side of the substrate to form a collector layer.

Disclosed herein are methods for backside wafer dopant activation using a high-temperature ion implant. In some embodiments, a method may include forming a semiconductor device atop a first main side of a substrate, and performing a high-temperature ion implant to a second main side of the substrate, wherein the first main side of the substrate is opposite the second main side of the substrate. The method may further include performing a second ion implant to the second main side of the substrate to form a collector layer.

A thin non-punch-through semiconductor device with a patterned collector layer on the collector side is proposed. The thin NPT RC-IGBT semiconductor device has a collector layer with a pattern of p/n shorts, an emitter side structured as a functional MOS cell, a base layer arranged between the emitter and the collector sides, but without the use of a buffer/field-stop layer. A low doped bipolar gain control layer having a thickness of less than 10 μm may be used in combination with a short pattern of the collector to reduce the bipolar gain and achieve thinner devices with lower losses and high operating temperature capability. The doping concentration of the base layer and a thickness of the base layer are adapted such that the distance from the end of the electric field region to the patterned collector, at breakdown voltage, is less than 15% of the total device thickness.

A Metal Oxide Semiconductor (MOS) transistor cell design has multiple trench recesses embedding trench gate electrodes longitudinally extending in a third dimension, with interconnected first base layer, source regions, and a second base layer covering portions of the regions between adjacent trench recesses and longitudinally extending in the same third dimension. When a control voltage greater than a threshold value is applied on the trench gate electrodes, no vertical MOS channels are formable on the trench walls because each of trench recesses abuts at least one source regions and a connected highly doped second base layer. Instead, the charge carriers flow from a singular point within the source region, into a radial MOS channel formed only on the lateral walls of those trench regions abutting the first base layer, but not the higher doped second base layer.

A semiconductor device is proposed. The semiconductor device includes a semiconductor substrate including a RC-IGBT with a diode area. The diode area includes a p-doped anode region and an n-doped emitter efficiency adjustment region. At least one of the p-doped anode region or the n-doped emitter efficiency adjustment region includes deep level dopants.