A silicon carbide substrate having a gate insulating film provided in contact with a first main surface, having a gate electrode provided in contact with the gate insulating film, and having a source region exposed from first main surface is prepared. A first recess having a first inner wall surface is formed in an interlayer insulating film by performing a first isotropic etching with respect to the interlayer insulating film with use of a mask layer. A second recess having a second inner wall surface is formed by performing a first anisotropic etching with respect to the interlayer insulating film and the gate insulating film with use of the mask layer and thereby exposing the source region from gate insulating film. An interconnection is formed which is arranged in contact with the first inner wall surface and the second inner wall surface and electrically connected to a source electrode.

A method for manufacturing a wide bandgap junction harrier Schottky diode (1) having an anode side (10) and a cathode side (15) is provided, wherein an (n±) doped cathode layer (2) is arranged on the cathode side (15), at least one p doped anode layer (3) is arranged on the anode side (10), an (n−) doped drift layer (4) is arranged between the cathode layer (2) and the at least one anode layer (3), which drift layer (4) extends to the anode side (10), wherein the following manufacturing steps are performed: a) providing an (n+) doped wide bandgap substrate(100), b) creating the drift layer (4) on the cathode layer (2), c) creating the at least one anode layer (3) on the drift layer (4), d) applying a first metal layer (5) on the anode side (10) on top of the drift layer (4) for forming a Schottky contact (55), characterized in, that e) creating a second metal layer (6) on top of at least one anode layer (3), wherein after having created the first and the second metal layer (5, 6), a metal layer on top of the at least one anode layer (3) has a second thickness (64) and a metal layer on top of the drift layer (4) has a first thickness (54), wherein the second thickness (64) is smaller than the first thickness (54), 1) then performing a first heating step (63) at a first temperature, by which due the second thickness (64) being smaller than the first thickness (54) an ohmic contact (65) is formed at the interface between the second metal layer (6) and the at least one anode layer (3), wherein performing the first healing step (63) such that a temperature below the first metal layer (5) is kept below a temperature for forming an ohmic contact.

An interlayer is used to reduce Fermi-level pinning phenomena in a semiconductive device with a semiconductive substrate. The interlayer may be a rare-earth oxide. The interlayer may be an ionic semiconductor. A metallic barrier film may be disposed between the interlayer and a metallic coupling. The interlayer may be a thermal-process combination of the metallic barrier film and the semiconductive substrate. A process of forming the interlayer may include grading the interlayer. A computing system includes the interlayer.

Semiconductor devices and their manufacturing methods are disclosed herein, and more particularly to semiconductor devices including a transistor having gate all around (GAA) transistor structures and manufacturing methods thereof. Different thickness in an epi-growth scheme is adopted to create different sheet thicknesses within the same device channel regions for use in manufacturing vertically stacked nanostructure (e.g., nanosheet, nanowire, or the like) GAA devices. A GAA device may be formed with a vertical stack of nanostructures in a channel region with a topmost nanostructure of the vertical stack being thicker than the other nanostructures of the vertical stack. Furthermore, an LDD portion of the topmost nanostructure may be formed as the thickest of the nanostructures in the vertical stack.

A method includes providing a layer of porous silicon carbide supported by a silicon carbide substrate, providing a layer of epitaxial silicon carbide on the layer of porous silicon carbide, forming a plurality of semiconductor devices in the layer of epitaxial silicon carbide, and separating the substrate from the layer of epitaxial silicon carbide at the layer of porous silicon carbide. Additional methods are described.

A method includes: providing a layer of porous silicon carbide supported by a silicon carbide substrate; providing a layer of epitaxial silicon carbide on the layer of porous silicon carbide; forming semiconductor devices in the layer of epitaxial silicon carbide; and separating the silicon carbide substrate from the layer of epitaxial silicon carbide at the layer of porous silicon carbide. The layer of porous silicon carbide includes dopants defining a resistivity of the layer of porous silicon carbide. The resistivity of the layer of porous silicon carbide is different from a resistivity of the silicon carbide substrate. Additional methods are described.

Semiconductor devices and their manufacturing methods are disclosed herein, and more particularly to semiconductor devices including a transistor having gate all around (GAA) transistor structures and manufacturing methods thereof. Different thickness in an epi-growth scheme is adopted to create different sheet thicknesses within the same device channel regions for use in manufacturing vertically stacked nano structure (e.g., nanosheet, nanowire, or the like) GAA devices. A GAA device may be formed with a vertical stack of nanostructures in a channel region with a topmost nanostructure of the vertical stack being thicker than the other nanostructures of the vertical stack. Furthermore, an LDD portion of the topmost nano structure may be formed as the thickest of the nanostructures in the vertical stack.

A method includes providing a layer of porous silicon carbide supported by a silicon carbide substrate, providing a layer of epitaxial silicon carbide on the layer of porous silicon carbide, forming a plurality of semiconductor devices in the layer of epitaxial silicon carbide, and separating the substrate from the layer of epitaxial silicon carbide at the layer of porous silicon carbide. Additional methods are described.

A method includes providing a first layer of epitaxial silicon carbide supported by a silicon carbide substrate, providing a second layer of epitaxial silicon carbide on the first layer, forming a plurality of semiconductor devices in the second layer, and separating the substrate from the second layer at the first layer. The first layer includes a plurality of voids.

Semiconductor devices and their manufacturing methods are disclosed herein, and more particularly to semiconductor devices including a transistor having gate all around (GAA) transistor structures and manufacturing methods thereof. Different thickness in an epi-growth scheme is adopted to create different sheet thicknesses within the same device channel regions for use in manufacturing vertically stacked nanostructure (e.g., nanosheet, nanowire, or the like) GAA devices. A GAA device may be formed with a vertical stack of nanostructures in a channel region with a topmost nanostructure of the vertical stack being thicker than the other nanostructures of the vertical stack. Furthermore, an LDD portion of the topmost nanostructure may be formed as the thickest of the nanostructures in the vertical stack.