A semiconductor device having a high cutoff resistance capable of suppressing local current/electric field concentration and current concentration at a chip termination portion due to an electric field variation between IGBT cells due to a shape variation and impurity variation during manufacturing. The semiconductor device is characterized by including an emitter electrode formed on a front surface of a semiconductor substrate via an interlayer insulating film, a collector electrode formed on a back surface of the semiconductor substrate, a first semiconductor layer of a first conductivity type in contact with the collector electrode, a second semiconductor layer of a second conductivity type, a central area cell, and an outer peripheral area cell located outside the central area cell.

A p-type semiconductor region is formed in a front surface side of an n-type semiconductor substrate. An n-type field stop (FS) region including protons as a donor is formed in a rear surface side of the semiconductor substrate. A concentration distribution of the donors in the FS region include first, second, third and fourth peaks in order from a front surface to the rear surface. Each of the peaks has a peak maximum point, and peak end points formed at both sides of the peak maximum point. The peak maximum points of the first and second peaks are higher than the peak maximum point of the third peak. The peak maximum point of the third peak is lower than the peak maximum point of the fourth peak.

Embodiments of the disclosure provide an integrated circuit (IC) structure with a diode over a lateral bipolar transistor. A structure according to the disclosure may include a lateral bipolar transistor within a monocrystalline semiconductor over a substrate. An insulator layer is over a portion of the monocrystalline semiconductor. A diode is within a polycrystalline semiconductor on the insulator layer. A cathode of the diode is coupled to a first well within the monocrystalline semiconductor. The first well defines one of an emitter terminal and a collector terminal of the lateral bipolar transistor.

A semiconductor device is an IGBT of a trench-gate structure and has a storage region directly beneath a p.sup.-type base region. The semiconductor device has gate trenches and dummy trenches as trenches configuring the trench-gate structure. An interval (mesa width) at which the trenches are disposed is in a range of 0.7 m to 2 m. In each of the gate trenches, a gate electrode of a gate potential is provided via a first gate insulating film. In each of the dummy trenches, a dummy gate electrode of an emitter potential is provided via a second gate insulating film. A total number of the gate electrode is in a range of 60% to 84% of a total number of the dummy electrodes.

A semiconductor device includes a first region in which a drift, base, and accumulation regions are stacked. Transistor cells are each provided partially in the first region and include at least one trench extending into the drift region. A second region includes a well region provided on an edge termination region side surrounding the first region. A third region of a predetermined width is between the first and second regions, inside of which the transistor cells are partially provided. A bottom region is provided in the first region, adjacent to a bottom of the trench, and between the accumulation and drift regions, the bottom region not extending into the third region, its upper surface located below the base region's lower surface; and first and second electrodes configured to flow current therebetween. The bottom region is spaced apart from the base region by the accumulation region in the depth direction.

A semiconductor device includes a semiconductor substrate, a top electrode in contact with a top surface of the semiconductor substrate, a bottom electrode in contact with a bottom surface of the semiconductor substrate, and an oxide film in contact with the top surface of the semiconductor substrate. The semiconductor substrate includes an element region and an outer peripheral region. The element region is a region where the top electrode is in contact with the top surface of the semiconductor substrate. The outer peripheral region is a region where the oxide film is in contact with the top surface of the semiconductor substrate, and is located between the element region and an outer peripheral end surface of the semiconductor substrate. The element region includes a semiconductor element connected between the top electrode and the bottom electrode. The outer peripheral region includes surface high-voltage-breakdown regions, deep high-voltage-breakdown regions, and a drift region.

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 diode and method of design the layout of the same having reduced parasitic capacitance is disclosed. In particular, the diode for providing fast response protection of an RF circuit from a high power noise event, such as an ESD, voltage spike, power surge or other noise is disclose. The parasitic capacitance in disclosed circuit is a greatly reduced compared to the prior art, thus significantly increasing the speed of the response to dissipate all high power noise events.

An object of the present invention is to provide a semiconductor device capable of eliminating unevenness of current distribution in a plane. A semiconductor device according to the present invention is a semiconductor device including a transistor cell region where a plurality of transistor cells is arranged on a semiconductor substrate, the semiconductor device including an electrode pad which is arranged avoiding the transistor cell region on the semiconductor substrate and is electrically connected to a one-side current electrode of each of the cells, in which the transistor cell region contains a plurality of regions each of which has a different current drive capability from each other depending on a distance from the electrode pad.

A semiconductor wafer processing system for processing a semiconductor wafer is presented. The semiconductor wafer processing system comprises: a trench production apparatus configured to produce trenches in the semiconductor wafer, the trenches being arranged next to each other along a first lateral direction (X); a trench filling apparatus configured to epitaxially fill the trenches with a doped semiconductor material; and a controller operatively coupled to at least one of the trench production apparatus and the trench filling apparatus, wherein the controller is configured to control at least one of the trench production apparatus and the trench filling apparatus in dependence of a parameter, the parameter being indicative of at least one of a variation of dopant concentrations of the doped semiconductor material along the first lateral direction (X) that is to be expected when carrying out the epitaxially filling and a deviation of an expected average of the dopant concentrations from a predetermined nominal value.