A lateral DMOS having a well region, a source region, a drain region, a first gate region and a second gate region. The first gate region may be positioned atop a portion of the well region near the source region side. The second gate region may be formed in a portion of the well region near the drain region side. The second gate region includes a shallow trench isolation structure formed in a shallow trench opened from a top surface of the well region and extended vertically into the well region, and having a first sidewall contacting with the drain region or abut the drain region, and further having a second sidewall opposite to the first sidewall and laterally extended below the first gate region.

A semiconductor device includes a semiconductor substrate, an epitaxial layer disposed on the semiconductor substrate, a cell zone including multiple unit cells disposed in the epitaxial layer opposite to the semiconductor substrate, a transition zone having a doped region and surrounding the cell zone, a source electrode unit disposed on the epitaxial layer opposite to the semiconductor substrate, and multiple gate electrode units. Each unit cell includes a well region, a source region disposed in the well region, and a well contact region extending through the source region to contact the well region. A method for manufacturing the semiconductor device is also disclosed.

A semiconductor device is provided that includes a substrate, a channel with the channel positioned on the top of the substrate, and a drift with the drift positioned on the top of the channel. The semiconductor device further includes a first poly positioned in the channel and the drift, and a second poly positioned on the top of the first poly and positioned in the drift. The first poly and the second poly are isolated by a gate oxide and a RESURF oxide, respectively, from the channel and from the drift.

A power semiconductor device includes a semiconductor layer structure comprising a wide bandgap semiconductor material. The semiconductor layer structure includes a drift region of a first conductivity type and a plurality of fin structures protruding from the drift region. The fin structures comprise respective source regions of the first conductivity type and respective channel regions between the respective source regions and the drift region. Related devices and methods are also discussed.

A high voltage device includes: a semiconductor layer, a well, a body region, a gate, a source, a drain, and a drift oxide region. The semiconductor layer is formed on a substrate, wherein the semiconductor layer has at least one trench. The well is formed in the semicoducotor layer. The body region is formed in the well. The gate is formed on the well, and is in contact with the well. The source and the drain are located below, outside, and at different sides of the gate, in the body region and the well respectively. The drift oxide region is formed on a drift region, wherein a bottom surface of the drift oxide region is higher than a bottom surface of the trench.

A gate-all-around (GAA) high voltage transistor of the laterally double-diffused metal-oxide semiconductor (LDMOS) type has a loop-shaped gate electrode disposed below a surface of a semiconductor substrate. The loop-shaped gate electrode surrounds a vertical channel formed by a first source/drain region, a body region, and a diffusion region. The first source/drain region is on top, the body region is in the middle, and the diffusion region is underneath. A loop-shaped shallow trench isolation (STI) region surrounds the loop-shaped gate electrode. The diffusion region begins inside the loop-shaped gate electrode, extends under the loop-shaped gate electrode and the loop-shaped STI region, and rises outside the loop-shaped STI region to join with a second source/drain region. This structure allows pitch to be reduced by 40% or linear drive current to be doubled in comparison to an asymmetric NMOS transistor providing otherwise equivalent functionality.

A semiconductor structure includes a substrate, an isolation layer, a dielectric layer, an insulation layer, a conductor and a capping layer. The substrate has a concave portion. The isolation layer is located on a top surface of the substrate. The dielectric layer is located on the isolation layer. The insulation layer is located on a surface of the concave portion and extends to a sidewall of the isolation layer. The conductor is located on the insulation layer in the concave portion. The conductor has a first top surface and a second top surface, and the first top surface is closer to the dielectric layer than the second top surface. The capping layer is located in the concave portion and covers the conductor.

In the present invention, in a FinFET having a channel forming region on a surface of a fin that is a semiconductor layer protruding on an upper surface of a substrate, a channel at a corner of the fin is prevented from becoming an ON state with a low voltage and a steep ON/OFF operation is made possible. As a means thereof, in a MOSFET that has a plurality of trenches, each of which have embedded therein a gate electrode, on an upper surface of an n-type epitaxial substrate provided with a drain region on a bottom surface and that has a channel region formed on a surface of a fin which is a protrusion part between the trenches adjacent to each other, a p-type body layer that constitutes a lateral surface of the fin, and a p.sup.+-type semiconductor region that constitutes a corner which is an end of the upper surface of the fin, are formed.

A method for fabricating a transistor includes providing a substrate, having a gate region and a first trench in the substrate at a first side of the gate region; forming a first gate insulating layer, disposed on a first portion of the gate region, opposite to the first trench; forming a second gate insulating layer, disposed on a second portion of the gate region and a first portion of the first trench abutting to the gate region, wherein the second gate insulating layer is thicker than the first gate insulating layer; forming a gate layer, disposed on the first and second gate insulating layers, having a downward protruding portion corresponding to the first trench; forming a first doped region in the substrate at least under the first trench; and forming a second doped region in the substrate at a second side of the gate region.

A semiconductor power device having shielded gate structure in an active area and trench field plate termination surrounding the active area is disclosed. A Zener diode connected between drain metal and source metal or gate metal for functioning as a SD or GD clamp diode. Trench field plate termination surrounding active area wherein only cell array located will not cause BV degradation when SD or GD poly clamped diode integrated.