A semiconductor device includes a chip formed by a wide bandgap semiconductor and having a principal surface on which a semiconductor region of a first conductivity type is formed, a base impurity region of a second conductivity type formed in a surface layer portion of the semiconductor region, a first impurity region formed in a surface layer portion of the base impurity region, and a second impurity region of a conductivity type opposite to that of the first impurity region formed in the surface layer portion of the base impurity region, the second impurity region being adjacent to the first impurity region in a first direction, wherein the second impurity region is formed in a band shape extending in a second direction orthogonal to the first direction, and includes a projection portion selectively protruding toward the first impurity region in the first direction.

An integrated circuit package and the method of forming the same are provided. The integrated circuit package may include an integrated circuit die and a dielectric material on sidewalls of the integrated circuit die. The integrated circuit die may include a substrate, a protective structure in the substrate, an interconnect structure on the substrate, and a seal ring structure in the interconnect structure and in contact with the protective structure. The protective structure and the substrate may include a same semiconductor material, and the protective structure may include a first dopant and a second dopant different from the first dopant. The interconnect structure may include dielectric layers and conductive features in the dielectric layers. The seal ring structure may encircle the conductive features of the interconnect structure in a top-down view.

Semiconductor devices and processes for manufacturing semiconductors are described. A semiconductor device can include a drift region formed on a Silicon Carbide substrate. The semiconductor device can include a trench that penetrates through a source region and a channel and reaches the drift region. The semiconductor device can include an oxide region lining the trench. The oxide region can include a bottom portion, a lower side portion and an upper side portion. A thickness of the bottom portion and a thickness of the lower side portion can be greater than a thickness of the upper side portion. The semiconductor device can include a gate electrode formed in the trench lined with the oxide region. The semiconductor device can include a shield region in contact with a bottom portion of the trench. A width of the semiconductor region can be less than or equal to a width of the trench.

In a mesa region sandwiched between adjacent active trenches among mesa regions that are regions each sandwiched between adjacent trenches, a third semiconductor layer has regions discretely arranged in a first direction so as to be in contact with one active trench of the adjacent active trenches and not in contact with the other active trench, and regions discretely arranged in the first direction so as to be in contact with the other active trench and not in contact with the one active trench. In the mesa region sandwiched between the adjacent active trenches, a fourth semiconductor layer is disposed between the third semiconductor layer on the side in contact with the one active trench and the third semiconductor layer on the side in contact with the other active trench in plan view and between the respective regions of the third semiconductor layer discrete in the first direction.

An embodiment relates to a method obtaining a silicon carbide wafer comprising a first conductivity type substrate and a first conductivity type drift layer, forming a second conductivity type first well region within the first conductivity type drift layer, forming a first conductivity type source region within the second conductivity type first well region, forming a second conductivity type plug region under the first conductivity type source region, forming a gate oxide layer, forming a patterned gate metal layer, depositing an interlevel dielectric (ILD) layer, forming a first patterned mask layer on top of the ILD layer, and etching the ILD layer and the first conductivity type source region using the first patterned mask layer, and forming a silicide layer, wherein the silicide layer is in contact with a vertical sidewall of the first conductivity type source region and at-least one second conductivity type region.

An embodiment relates to a method obtaining a silicon carbide wafer comprising a first conductivity type substrate and a first conductivity type drift layer, forming a second conductivity type first well region within the first conductivity type drift layer, forming a first conductivity type source region within the second conductivity type first well region, forming a second conductivity type plug region under the first conductivity type source region, forming a gate oxide layer, forming a patterned gate metal layer, depositing an interlevel dielectric (ILD) layer, forming a first patterned mask layer on top of the ILD layer, and etching the ILD layer and the first conductivity type source region using the first patterned mask layer, and forming a silicide layer, wherein the silicide layer is in contact with a vertical sidewall of the first conductivity type source region and at-least one second conductivity type region.

A semiconductor structure includes a substrate, at least one first fin protruded from the substrate, and a 3D capacitor disposed over the substrate. The 3D capacitor includes a doped electrode conformally disposed in the first fin, a metal electrode disposed over the doped electrode, and a dielectric layer disposed between the doped electrode and the metal electrode.

A semiconductor device includes a first electrode and a second electrode. The first electrode is connected to a collector layer and a first portion on the collector layer side of a cathode layer. The second electrode is connected to a second portion of the cathode layer excluding the first portion. A work function of the first electrode is larger than a work function of the second electrode, and one of the first electrode and the second electrode and the semiconductor substrate sandwich another of the first electrode and the second electrode in a thickness direction of the semiconductor substrate.

A semiconductor device includes a first electrode and a second electrode. The first electrode is connected to a collector layer and a first portion on the collector layer side of a cathode layer. The second electrode is connected to a second portion of the cathode layer excluding the first portion. A work function of the first electrode is larger than a work function of the second electrode, and one of the first electrode and the second electrode and the semiconductor substrate sandwich another of the first electrode and the second electrode in a thickness direction of the semiconductor substrate.

A semiconductor structure manufacturing method includes forming, on a protective layer that is on an epitaxial layer, a first patterned hard mask including an opening surrounded by side surfaces of the first patterned hard mask. The first patterned hard mask includes a first dielectric layer, a semiconductor layer and a second dielectric layer sequentially formed on the protective layer. A first doped region is formed in the epitaxial layer below the opening through the first patterned hard mask. A second patterned hard mask is formed on the side surfaces of the first patterned hard mask, through which a second doped region is formed in the epitaxial layer. The first doped region is located along a sidewall of the second doped region. A third patterned hard mask surrounding the second patterned hard mask is formed, through which a third doped region is formed in the second doped region.