Disclosed is a superjunction semiconductor device (1) and a method for manufacturing the same and, more particularly, to a superjunction semiconductor device (1) and a method for manufacturing the same seeking to improve breakdown voltage characteristics of the device by effectively dispersing a lateral electric field in a ring region R in the lower portion of an epitaxial layer by forming first conductivity type floating impurity-doped regions in the lower portion of the epitaxial layer in the ring region R under a p-rich condition.

A method for manufacturing a semiconductor device is provided. A drift region and a compensation region are formed through a deep trench etching and a filling technology. A plurality of modulation doping regions are formed at a top of the drift region by an epitaxy and an ion implantation. A modulation region is introduced, wherein the modulation region flexibly modifies capacitance characteristics and achieve improved dynamic characteristics.

In one embodiment, a power semiconductor device may include a semiconductor substrate, wherein the semiconductor substrate comprises an active device region and a junction termination region. The power semiconductor device may also include a polysilicon layer, disposed over the semiconductor substrate. The polysilicon layer may include an active device portion, disposed over the active device region, and defining at least one semiconductor device; and a junction termination portion, disposed over the junction termination region, the junction termination portion defining a ring structure.

A VDMOS device and a fabrication method thereof are provided. The device includes unit cells which jointly form a cellular structure. The cellular structure includes spaced-apart source regions and surrounding gate regions. Some gate regions overlap to form gate intersections comprising separation regions; the others form non-intersecting gate regions. Each unit cell has a JFET region corresponding in position to one non-intersecting gate region and a JFET shielding region corresponding in position to one gate intersection. The difference in doping concentrations of different types of dopants in the JFET shielding region surpasses difference in doping concentrations in the JFET regions and therefore depletion layers disposed along diagonals of the gate intersections expand and merge more easily, thereby increasing breakdown voltage along the diagonals. Therefore, the device exhibits enhanced voltage tolerance and stability.

A parallel structure comprising source/drain and channel layers alternately stacked on a substrate, and gate stacks formed around peripheries of the channel layers. Each of the channel layers, the source/drain layers on upper and lower sides of the channel layer, and the gate stack formed around the channel layer, form a semiconductor device. In each semiconductor device, one of the source/drain layers is in contact with a first electrically-conductive channel disposed on an outer periphery of the active region, the other is in contact with a second electrically-conductive channel on the outer periphery of the active region, and the gate stack is in contact with a third electrically-conductive channel disposed on the outer periphery of the active region. The first electrically-conductive channel is common to the semiconductor devices, the second electrically-conductive channel is common to the semiconductor devices, and the third electronically-conductive channel is common to the semiconductor devices.

A MOSFET device die includes an active area formed on a semiconductor substrate. The active area includes a first active area portion and a second active area portion. At least one mesa is formed in the semiconductor substrate extending in a longitudinal direction through the active area. The at least one mesa includes a channel region extending in a longitudinal direction. The channel region includes low threshold voltage channel portions and high threshold voltage channel portions. The first active area portion includes the channel portions in a first ratio of low threshold voltage channel portions to high threshold voltage channel portions, and the second active area portion includes channel portions in a second ratio of low threshold voltage channel portions to high threshold voltage channel portions. The first ratio is larger than the second ratio.

Disclosed are a superjunction semiconductor device and a method of manufacturing the same. More particularly, the present disclosure relates to a superjunction semiconductor device and a method of manufacturing the same including one or more first conductivity type pillars in a ring region at least partially extending along a first direction, whereby it is possible to reduce electric field concentrations at a surface of the device, and thereby improve breakdown voltage characteristics and achieve an even or more even electric field distribution.

The present invention suppresses an increase in manufacturing cost and reduces switching noise. A field-effect transistor having a gate electrode embedded in a trench in an upper surface of a semiconductor substrate, a source region formed in the semiconductor substrate, and a drain region formed on a lower surface of the semiconductor substrate is provided with a gate wiring formed on the semiconductor substrate and being electrically connected to the gate electrode, a gate pad formed on the semiconductor substrate, a first resistor connected between the gate pad and the gate wiring and being configured to function when the field-effect transistor is turned ON, a second resistor connected between the gate pad and the gate wiring and being configured to function when the field-effect transistor is turned OFF, and a rectifier diode included in the first resistor or the second resistor between the gate pad and the gate wiring.

A semiconductor device is formed using a semiconductor substrate having a first main surface and a second main surface. A first semiconductor region of a first conductivity type is formed between the first main surface and the second main surface of the semiconductor substrate. A second semiconductor region is formed between the first semiconductor region and the first main surface. The first semiconductor region includes a hydrogen-related donor, and a concentration of the hydrogen-related donor of the first semiconductor region is equal to or larger than an impurity concentration of the first semiconductor region.

This disclosure relates to a semiconductor device, and associated method of manufacture. The semiconductor device includes, a MOSFET integrated with a p-n junction, the p-n junction arranged as a clamping diode across a source contact and a drain contact of the MOSFET. The MOSFET defines a first breakdown voltage, and the clamping diode defines a second breakdown voltage, and the first breakdown voltage is greater than the second breakdown voltage. A series resistance of the clamping diode includes a drift resistance and a clamping resistance, and the drift resistance is formed together with the clamping diode and the clamping resistance is formed independently from the clamping diode and configured to secure a uniform avalanche current.