A semiconductor device includes a semiconductor part, first to third electrodes, and first and second control electrodes. The semiconductor part is provided between the first and second electrodes. On the second electrode side of the semiconductor part, the first control electrode and the third electrode are provided in a first trench, and the second control electrode is provided in a second trench. The first control electrode is provided between the second and third electrode. In a first direction from the first control electrode toward the second control electrode, the first trench has first and second widths. The first width is a combined width of the third electrode and insulating portions provided on both sides of the third electrode. The second width is a combined width of the first control electrode and the gate insulating films on both sides thereof. The first width is greater than the second width.

A semiconductor device includes: a substrate, a first support structure, a first nanowire heterojunction, a source, a drain, and a ring-shaped gate. The substrate includes a first region, and a second region and a third region located on respective sides of the first region; the first support structure is located at least on the second region and the third region; the first nanowire heterojunction includes a first gate section corresponding to the first region, a first source section corresponding to the second region, and a first drain section corresponding to the third region; the first source section and the first drain section are located on the first support structure. The source is located on the first source section, the drain is located on the first drain section, and the ring-shaped gate wraps the first gate section.

Embodiments of the present disclosure provide an epitaxial structure of a semiconductor device and a method of manufacturing the same. The epitaxial structure includes a substrate, and an epitaxial layer located on a side of the substrate, the epitaxial layer including a nucleation layer located on a side of the substrate and a buffer layer located on a side of the nucleation layer away from the substrate, wherein a thickness of the buffer layer is inversely proportional to a thickness of the nucleation layer.

A III-N semiconductor channel is compositionally graded between a transition layer and a III-N polarization layer. In embodiments, a gate stack is deposited over sidewalls of a fin including the graded III-N semiconductor channel allowing for formation of a transport channel in the III-N semiconductor channel adjacent to at least both sidewall surfaces in response to a gate bias voltage. In embodiments, a gate stack is deposited completely around a nanowire including a III-N semiconductor channel compositionally graded to enable formation of a transport channel in the III-N semiconductor channel adjacent to both the polarization layer and the transition layer in response to a gate bias voltage.

A method of manufacturing a semiconductor device comprises: forming a doped region having a first conductive type in a semiconductor substrate, and forming a gate structure on the doped region; implanting doping ions having a second conductive type to a second region of the doped region along a vertical direction, so as to form a source/drain region having the second conductive type; implanting doping ions having the first conductive type to a first region of the doped region along a tilt direction inclining toward the gate structure, and then annealing, so as to form a Halo region extending to the gate structure from the source/drain region, wherein the first region is adjacent to the gate structure and the second region is located on the side of the first region facing away from the gate structure, and the first region and the second region have no overlap region.

A semiconductor device includes a semiconductor part, first to third electrodes, and first and second control electrodes. The semiconductor part is provided between the first and second electrodes. On the second electrode side of the semiconductor part, the first control electrode and the third electrode are provided in a first trench, and the second control electrode is provided in a second trench. The first control electrode is provided between the second and third electrode. In a first direction from the first control electrode toward the second control electrode, the first trench has first and second widths. The first width is a combined width of the third electrode and insulating portions provided on both sides of the third electrode. The second width is a combined width of the first control electrode and the gate insulating films on both sides thereof. The first width is greater than the second width.

The present disclosure provides a method for manufacturing a semiconductor structure, the mothed including: providing a substrate, a heterojunction structure, and a P-type semiconductor layer, which are distributed from bottom to top; forming a patterned mask layer on the P-type semiconductor layer, the patterned mask layer covering at least a portion of the P-type semiconductor layer in a gate region; removing an exposed portion of the P-type semiconductor layer by in-situ etching with a corrosive gas, by using the patterned mask layer as a mask; and then activating the P-type dopant ions in the P-type semiconductor layer.

The present invention discloses a stacked semiconductor chip structure and its process wherein the stacked semiconductor chip structure comprises a substrate as well as P-type semiconductor layers and N-type semiconductor layers which are stacked one by one on the substrate, wherein the P-type semiconductor layers and the N-type semiconductor layers are arranged alternately, there are at least two P-type semiconductor layers and at least two N-type semiconductor layers. The present invention uses the chemical vapor deposition method to stack and form the P-type semiconductor layers and the N-type semiconductor layers, uses the physical etching and the plasma cleaning to form the conducting layers and thus avoids using the photo masks, the photo resist and the mask aligners for the manufacture of semiconductor chips, reduces the complexity of semiconductor chip processes and increases the yield of semiconductor chip products.

A metal-oxide semiconductor field effect transistor (MOSFET) includes a source region and a drain region of a first conductivity type. The MOSFET additionally include a body region of a second conductivity type, where the body region underlies at least a portion of the source region and the drain region. The MOSFET further includes a buried region of the first conductivity type, where the buried region is disposed between the body region and a substrate, where the buried region is configured to reduce a capacitance between the source region and the drain region in response to an indicated voltage applied between the body region and the buried region.

Some embodiments of the present disclosure provide a semiconductor device. The semiconductor device includes a semiconductive substrate. A donor-supply layer is over the semiconductive substrate. The donor-supply layer includes a top surface. A gate structure, a drain, and a source are over the donor-supply layer. A passivation layer covers conformably over the gate structure and the donor-supply layer. A gate electrode is over the gate structure. A field plate is disposed on the passivation layer between the gate electrode and the drain. The field plate includes a bottom edge. The gate electrode having a first edge in proximity to the field plate, the field plate comprising a second edge facing the first edge, a horizontal distance between the first edge and the second edge is in a range of from about 0.05 to about 0.5 micrometers.