The present disclosure provides an embodiment of a fin-like field-effect transistor (FinFET) device. The device includes a substrate having a first gate region, a first fin structure over the substrate in the first gate region. The first fin structure includes an upper semiconductor material member, a lower semiconductor material member, surrounded by an oxide feature and a liner wrapping around the oxide feature of the lower semiconductor material member, and extending upwards to wrap around a lower portion of the upper semiconductor material member. The device also includes a dielectric layer laterally proximate to an upper portion of the upper semiconductor material member. Therefore the upper semiconductor material member includes a middle portion that is neither laterally proximate to the dielectric layer nor wrapped by the liner.

A method of producing a plurality of semiconductor chips includes a) providing a carrier substrate having a first major face and a second major face opposite the first major face; b) forming a diode structure between the first major face and the second major face, the diode structure electrically insulating the first major face from the second major face at least with regard to one polarity of an electrical voltage; c) arranging a semiconductor layer sequence on the first major face of the carrier substrate; and d) singulating the carrier substrate with the semiconductor layer sequence into a plurality of semiconductor chips.

A method for manufacturing a semiconductor device is provided. The method includes operations below. First, an epitaxial layer is formed on a substrate. Then, a trench is formed in the epitaxial layer. Then, a first dielectric layer and a shield layer are formed in the trench, in which the shield layer is embedded within the first dielectric layer. Then, a spacer layer is formed in the trench and on the first dielectric layer. Finally, a second dielectric layer and a gate are formed in the trench and on the spacer layer, and a source is formed in the epitaxial layer surrounding the trench, in which the gate is embedded within the second dielectric layer, and the source surrounds the gate.

A semiconductor device includes: a substrate having a first region and a second region; a first fin-shaped structure on the first region and a second fin-shaped structure on the second region; a first bump on the first region; a first doped layer on the first fin-shaped structure and the bump; and a gate structure covering the bump.

An integrated circuit and method of forming the integrated circuit, including the steps of forming channels partially into a thickness of a semiconductor layer or through the thickness of the semiconductor layer and partially through a thickness of a substrate layer on which the semiconductor layer was formed. The method may then include underfilling or overfilling the channels with diamond. If underfilled, a remainder of the channels may be filled in with nucleation buffer layers or additional semiconductor material. If overfilled, the diamond may be selectively polished down to form a planar surface with the semiconductor layer. Next, the method may include forming an active device layer over the semiconductor material and diamond. The method may also include thinning the substrate layer down to the diamond and then placing a heat sink in physical contact with the diamond in the channel.

A semiconductor structure includes a semiconductor substrate having a first electrical portion, a second electrical portion, and a bridged conductive layer. The first electrical portion includes a first semiconductor well, a second semiconductor well in the first semiconductor well, and a third semiconductor well and a fourth semiconductor well in the second semiconductor well. The second electrical portion includes a fifth semiconductor well, a semiconductor layer in the fifth semiconductor well, and a sixth semiconductor well and a seventh semiconductor well in the fifth semiconductor well. The semiconductor layer has separated first and second portions. The bridged conductive layer connects the fourth semiconductor well and the sixth semiconductor well.

In accordance with an embodiment, a semiconductor component includes a plurality of layers of compound semiconductor material over a body of semiconductor material and first and second filled trenches extending into the plurality of layers of compound semiconductor material. The first trench has first and second sidewalls and a floor and a first dielectric liner over the first and second sidewalls and the second trench has first and second sidewalls and a floor and second dielectric liner over the first and second sidewalls of the second trench.

A method for fabricating a semiconductor device may include receiving a gated substrate comprising a substrate with a channel layer and a gate structure formed thereon, over-etching the channel layer to expose an extension region below the gate structure, epitaxially growing a halo layer on the exposed extension region using a first in-situ dopant and epitaxially growing a source or drain on the halo layer using a second in-situ dopant, wherein the first in-situ dopant and the second in-situ dopant are of opposite doping polarity. Using an opposite doping polarity may provide an energy band barrier for the semiconductor device and reduce leakage current. A corresponding apparatus is also disclosed herein.

A semiconductor device may include a drift region having a first conductivity type, a source region having the first conductivity type, and a well region having a second conductivity type disposed adjacent to the drift region and adjacent to the source region. The well region may include a channel region that has the second conductivity type disposed adjacent to the source region and proximal to a surface of the semiconductor device cell. The channel region may include a non-uniform edge that includes at least one protrusion.

A performance of a power semiconductor device is improved. A power semiconductor device including unit cells UR and UL cyclically arranged in an X direction and a Y direction perpendicular to each other and a plurality of end cells is used. The unit cells UR and UL are alternately arranged in the X direction, the plurality of end cells include an X-end cell XL, Y-end cells YR and YL, an XY-end cell XY1L, and an XY-end cell XY2L for an optional region, each number of arrangement cycles of the unit cells UR and UL in the Y direction changes depending on repetition cycle coordinates in the X direction, each of the cyclically-arranged unit cells UR and UL is adjacent to any of the plurality of end cells at an endmost portion of arrangement cycle in each of the X direction and the Y direction, and regions having the plurality of end cells are different in an electric property from the unit cells UR and UL.