A semiconductor device includes a gate extraction portion extracted from a gate electrode and extending from an active region to an outer peripheral region so as to be disposed above an end portion of a field insulating film. The end portion of the gate field insulating film above which the gate extraction portion is disposed is inclined in such a manner that a thickness of the field insulating film increases in a direction from the active region toward the outer peripheral region.

A semiconductor device includes an N+ type substrate, an N− type layer disposed on a first surface of the N+ type substrate and having a trench opened to a surface opposite to the surface facing the N+ type substrate, a P type region disposed in the N− type layer and disposed on a side surface of the trench, a gate electrode disposed in the trench, and a source electrode and a drain electrode insulated from the gate electrode. The N− type layer includes a P type shield region covering a bottom surface and an edge of the trench.

In a trench gate type power MOSFET having a super-junction structure, both improvement of a breakdown voltage of a device and reduction of on-resistance are achieved. The trench gate and a column region are arranged so as to be substantially orthogonal to each other in a plan view, and a base region (channel forming region) and the column region are arranged separately in a cross-sectional view.

In an embodiment, a semiconductor device is provided that includes a main transistor having a load path, a sense transistor configured to sense a main current flowing in the load path of the main transistor, and at least one bypass diode structure configured to protect the sense transistor. The at least one bypass diode structure is electrically coupled in parallel with the sense transistor.

Methods may include providing a device structure having a shielding layer formed beneath each trench in a MOSFET to protect trench corner breakdown. The method may include providing a device structure comprising an epitaxial layer, a well over the epitaxial layer, and a source layer over the well, and providing a plurality of trenches through the device structure. The method may further include forming a shielding layer in the device structure by directing ions into the plurality of trenches.

There is provided a semiconductor device including: a semiconductor layer including a main surface; a plurality of trenches including a plurality of first trench portions and a plurality of second trench portions, respectively; an insulating layer formed in an inner wall of each of the second trench portions; a first electrode buried in each of the second trench portions with the insulating layer interposed between the first electrode and each of the second trench portions; a plurality of insulators buried in the first trench portions so as to cover the first electrode; a contact hole formed at a region between the plurality of first trench portions in the semiconductor layer so as to expose the plurality of insulators; and a second electrode buried in the contact hole.

Aspects of the present disclosure are directed to circuitry operable with enhanced capacitance and mitigation of avalanche breakdown. As may be implemented in accordance with one or more embodiments, an apparatus and/or method involves respective transistors of a cascode circuit, one of which controls the other in an off state by applying a voltage to a gate thereof. A plurality of doped regions are separated by trenches, with the conductive trenches being configured and arranged with the doped regions to provide capacitance across the source and the drain of the second transistor, and restricting voltage at one of the source and the drain of the second transistor, therein mitigating avalanche breakdown of the second transistor.

A power semiconductor device is disclosed. The device includes a semiconductor body coupled to a first load terminal structure and a second load terminal structure, a first cell and a second cell. A first mesa is included in the first cell, the first mesa including: a first port region and a first channel region. A second mesa included in the second cell, the second mesa including a second port region. A third cell is electrically connected to the second load terminal structure and electrically connected to a drift region. The third cell includes a third mesa comprising: a third port region, a third channel region, and a third control electrode.

A power semiconductor device is disclosed. In one example, the device includes a semiconductor body coupled to a first load terminal structure and a second load terminal structure. An active cell field is implemented in the semiconductor body. The active cell field is surrounded by an edge termination zone. A plurality of first cells and a plurality of second cells are provided in the active cell field. Each first cell includes a first mesa, the first mesa including: a first port region and a first channel region. Each second cell includes a second mesa, the second mesa including a second port region. The active cell field is surrounded by a drainage region that is arranged between the active cell field and the edge termination zone.

A power semiconductor device includes a semiconductor body coupled to first and second load terminal structures, an active cell field in the body, and a plurality of first and second cells in the active cell field. Each cell is electrically connected to the first load terminal structure and to a drift region. Each first cell includes a mesa having a port region electrically connected to the first load terminal structure, and a channel region coupled to the drift region. Each second cell includes a mesa having a port region of the opposite conductivity type electrically connected to the first load terminal structure, and a channel region coupled to the drift region. Each mesa is spatially confined in a direction perpendicular to a direction of the load current within the respective mesa, by an insulation structure and has a total extension of less than 100 nm in the direction.