A semiconductor device according to one or more embodiments is disclosed. A first semiconductor region includes a first semiconductor region, a second semiconductor region, a third semiconductor region, a first trench and a fourth semiconductor region. A second semiconductor region includes a fifth semiconductor region, a sixth semiconductor region, a second trench, and a second inner trench electrode. A dummy region includes a seventh semiconductor region that is arranged on the first semiconductor region between the first semiconductor region and the second semiconductor region, a third trench penetrating the seventh semiconductor region in a depth direction; and a third inner trench electrode electrically connected to the first inner trench electrode through a third insulating film in the third trench.

A semiconductor device and a manufacturing method thereof are provided. The semiconductor device includes: a first conductive type buried layer disposed on a substrate; a first conductive type deep well region, a second conductive type body region, and a first conductive type drift region which are disposed on the first conductive type buried layer; a source region disposed in the second conductive type body region; a drain region disposed in the first conductive type deep well region; and a gate electrode disposed on the second conductive type body region and the first conductive type drift region.

A field effect transistor includes first section and second sections. The first section includes a drift layer. A first P-well is disposed over the drift layer. A first N-source is disposed over the first P-well. A first channel is disposed in an upper portion of the first P-well. The second section includes an area P-well disposed within the drift layer and formed integral with the first P-well. The area P-well includes sidewalls that extend upwards from the drift layer to form an enclosed structure with an outer perimeter and an inner perimeter. An area N-source surrounds the outer perimeter and is formed integral with the first N-source. An upwardly extending intermediate portion of the drift layer extends upwards though the inner perimeter. A second channel is disposed in an upper portion of the sidewalls and is bounded by the inner perimeter and outer perimeter of the sidewalls.

An object of the present invention is to further improve electric characteristics such as ON-resistance or an ON-breakdown voltage in a semiconductor device having a lateral MOS transistor. In a semiconductor device having a lateral MOS transistor, a buried electrode is formed at a part of an isolation insulating film located between a drain region and a gate electrode. The buried electrode includes a buried part. The buried part is formed from the surface of the isolation insulating film up to a depth corresponding to a thickness thinner than that of the isolation insulating film. The buried electrode is electrically coupled to the drain region.

A semiconductor device includes a semiconductor body with transistor cells arranged in an active area and absent in an edge area between the active area and a side surface. A field dielectric adjoins a first surface of the semiconductor body and separates, in the edge area, a conductive structure connected to gate electrodes of the transistor cells from the semiconductor body. The field dielectric includes a transition from a first vertical extension to a second, greater vertical extension. The transition is in the vertical projection of a non-depletable extension zone in the semiconductor body, wherein the non-depletable extension zone has a conductivity type of body/anode zones of the transistor cells and is electrically connected to at least one of the body/anode zones.

A semiconductor device having a vertical drain extended MOS transistor may be formed by forming deep trench structures to define vertical drift regions of the transistor, so that each vertical drift region is bounded on at least two opposite sides by the deep trench structures. The deep trench structures are spaced so as to form RESURF regions for the drift region. Trench gates are formed in trenches in the substrate over the vertical drift regions. The body regions are located in the substrate over the vertical drift regions.

In an embodiment, a semiconductor device includes a semiconductor substrate having a bulk resistivity 100 Ohm.cm, a front surface and a rear surface, at least one LDMOS transistor in the semiconductor substrate, and a RESURF structure. The RESURF structure includes a doped buried layer arranged in the semiconductor substrate, spaced at a distance from the front surface and the rear surface, and coupled with at least one of a channel region and a body contact region of the LDMOS transistor.

A lateral superjunction MOSFET device includes multiple transistor cells connected to a lateral superjunction structure, each transistor cell including a conductive gate finger, a source region finger, a body contact region finger and a drain region finger arranged laterally within each transistor cell. Each of the drain region fingers, the source region fingers and the body contact region fingers is a doped region finger having a termination region at an end of the doped region finger. The lateral superjunction MOSFET device further includes a termination structure formed in the termination region of each doped region finger and including one or more termination columns having the same conductivity type as the doped region finger and positioned near the end of the doped region finger. The one or more termination columns extend through the lateral superjunction structure and are electrically unbiased.

A semiconductor device includes a semiconductor region with a charge balance region on a junction blocking region, the junction blocking region having a lower doping concentration. The junction blocking region extends between a pair of trench structures in cross-sectional view. The trench structures are provided in the semiconductor region and include at least one insulated electrode. In some embodiments, the semiconductor device further includes a first doped region disposed between the pair of trench structures. The semiconductor device may further include one or more features configured to improve operating performance. The features include a localized doped region adjoining a lower surface of a first doped region and spaced apart from the trench structure, a notch disposed proximate to the lower surface of the first doped region, and/or the at least one insulated electrode configured to have a wide portion adjoining a narrow portion.

A horizontal current bipolar transistor comprises a substrate of first conductivity type, defining a wafer plane parallel to said substrate; a collector drift region above said substrate, having a second, opposite conductivity type, forming a first metallurgical pn-junction with said substrate; a collector contact region having second conductivity type above said substrate and adjacent to said collector drift region; a base region comprising a sidewall at an acute angle to said wafer plane, having first conductivity type, and forming a second metallurgical pn-junction with said collector drift region; and a buried region having first conductivity type between said substrate and said collector drift region forming a third metallurgical pn-junction with the collector drift region. An intercept between an isometric projection of said base region on said wafer plane and an isometric projection of said buried region on said wafer plane is smaller than said isometric projection of said base region.