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 semiconductor device, such as a laterally diffused metal-oxide-semiconductor (LDMOS) transistor, includes a semiconductor substrate in which a source region and a drain region are disposed. The drain region has a drain finger terminating at a drain end. A gate structure is supported by the semiconductor substrate between the source region and the drain region, the gate structure extending laterally beyond the drain end. A drift region in the semiconductor substrate extends laterally from the drain region to at least the gate structure. The drift region is characterized by a first distance between a first sidewall of the drain finger and a second sidewall of the gate structure, and the gate structure is laterally tilted away from the drain region at the drain end of the drain finger to a second distance that is greater than the first distance.

A semiconductor device includes a chip that includes a mounting surface, a non-mounting surface, and a side wall connecting the mounting surface and the non-mounting surface and has an eaves portion protruding further outward than the mounting surface at the side wall and a metal layer that covers the mounting surface.

A transistor arrangement is disclosed. The transistor arrangement includes a first transistor device and a second transistor device. The first transistor device and the second transistor device are connected in series and integrated in a common semiconductor body. The first transistor device is a lateral superjunction transistor device and is integrated in a first device region of the semiconductor body. The second transistor device is a lateral transistor device and is integrated in at least one second device region of the semiconductor body. The at least one second device region is spaced apart from the first device region.

A silicon carbide semiconductor device includes a silicon carbide substrate having a first main surface and a second main surface opposite to the first main surface. A gate trench is provided in the first main surface. The gate trench is defined by side surfaces and a bottom surface. The side surfaces penetrate the source region and the body region to reach the drift region. The bottom surface connects to the side surfaces. The gate trench extends in a first direction parallel to the first main surface. The silicon carbide substrate further includes an electric field relaxation region that is the second conductive type, the electric field relaxation region being provided between the bottom surface and the second main surface and extending in the first direction, and a connection region that is the second conductive type, the connection region electrically connecting a contact region to the electric field relaxation region. In a plan view in a direction normal to the first main surface, the gate trench and the electric field relaxation region are disposed on a virtual line that extends in the first direction, and the connection region is in contact with the electric field relaxation region on the virtual line.

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.

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.

Provided is a manufacturing method of a semiconductor device comprising a semiconductor substrate which includes a first surface and a second surface which is on an opposite side of the first surface, the method comprising: a front surface processing for providing a first resist to the first surface of the semiconductor substrate and processing the first surface; a first protective film forming for forming a first protective film above the first surface of the semiconductor substrate; a second protective film forming for forming a second protective film above the first protective film, wherein a material of the second protective film is different from that of the first protective film; a back surface processing for processing the second surface of the semiconductor substrate; and a protective film removing for selectively removing the second protective film.

A semiconductor device and method of manufacturing the same are provided. The semiconductor device includes a substrate and a first isolation structure which has a first corner. The semiconductor device also includes a first well region with a first conductive type. The semiconductor device includes further includes a gate structure over the first well region and covers a portion of the first corner of the first isolation structure. In addition, the semiconductor device includes a first doped region and a second doped region disposed on two opposites of the gate structure. Each of the first doped region and the second doped region has the first conductive type. The semiconductor device also includes a first counter-doped region in the first well region with a second conductive type different from the first conductive type. The first counter-doped region covers the first corner of the first isolation structure.

An integrated circuit has a P-type substrate and an N-type LDMOS transistor. The LDMOS transistor includes a boron-doped diffused well (DWELL-B) and an arsenic-doped diffused well (DWELL-As) located within the DWELL-B. A first polysilicon gate having first sidewall spacers and a second polysilicon gate having second sidewall spacers are located over opposite edges of the DWELL-B. A source/IBG region includes a first source region adjacent the first polysilicon gate, a second source region adjacent the second polysilicon gate, and an integrated back-gate (IBG) region located between the first and second source regions. The first source region and the second source region each include a lighter-doped source sub-region, the IBG region including an IBG sub-region having P-type dopants, and the source/IBG region includes a heavier-doped source sub-region.