Provided is a two-dimensional large-area growth method for a chalcogen compound, the method including: depositing a film of a transition metal element or a Group V element on a substrate; thereafter, uniformly diffusing a vaporized chalcogen element, a vaporized chalcogen precursor compound or a chalcogen compound represented by MX.sub.2+ within the film; and, thereafter, forming a film of a chalcogen compound represented by MX.sub.2 by forming the chalcogen compound represented by MX.sub.2 through post-heating.

A method of forming an active device on a semiconductor wafer includes the steps of: forming a plurality of semiconductor fins on at least a portion of a semiconductor substrate; forming a dielectric layer on at least a portion of the semiconductor substrate, the dielectric layer filling gaps between adjacent fins; forming a plurality of gate structures on an upper surface of the dielectric layer; forming a channel region on the dielectric layer and under at least a portion of the gate structures, the channel region comprising a first crystalline semiconductor material; forming source and drain epitaxy regions on an upper surface of the dielectric layer and between adjacent gate structures, the source and rain regions being spaced laterally from one another; and replacing the channel region with a second crystalline semiconductor material after high-temperature processing used in fabricating the active device has been completed.

An integrated circuit structure includes a first vertical transistor and a second vertical transistor. The first vertical transistor includes a first semiconductor channel, a first top source/drain region over the first semiconductor channel, and a first top source/drain pad overlapping the first top source/drain region. The second vertical transistor includes a second semiconductor channel, a second top source/drain region over the second semiconductor channel, and a second top source/drain pad overlapping the second top source/drain region. A local interconnector interconnects the first top source/drain pad and the second top source/drain pad. The first top source/drain pad, the second top source/drain pad, and the local interconnector are portions of a continuous region, with no distinguishable interfaces between the first top source/drain pad, the second top source/drain pad, and the local interconnector.

Provided are optical devices and systems fabricated, at least in part, via printing-based assembly and integration of device components. In specific embodiments the present invention provides light emitting systems, light collecting systems, light sensing systems and photovoltaic systems comprising printable semiconductor elements, including large area, high performance macroelectronic devices. Optical systems of the present invention comprise semiconductor elements assembled, organized and/or integrated with other device components via printing techniques that exhibit performance characteristics and functionality comparable to single crystalline semiconductor based devices fabricated using conventional high temperature processing methods. Optical systems of the present invention have device geometries and configurations, such as form factors, component densities, and component positions, accessed by printing that provide a range of useful device functionalities. Optical systems of the present invention include devices and device arrays exhibiting a range of useful physical and mechanical properties including flexibility, shapeability, conformability and stretchablity.

The disclosed technology generally relates to semiconductor devices and more particularly to a gate-all-around semiconductor device, and methods of fabricating the same. In one aspect, the method comprises providing on a semiconductor substrate between STI regions at least one suspended nanostructure anchored by a source region and a drain region. The suspended nanostructure is formed of a crystalline semiconductor material that is different from a crystalline semiconductor material of the semiconductor substrate. A gate stack surrounds the at least one suspended nanostructure.

A bandgap tuneable p-GaN high electron mobility transistor (HEMT) having a structure stacked on a silicon carbide substrate. The device incorporates an indium nitride nucleation layer, followed by an aluminum nitride nucleation layer, and a first aluminum gallium nitride buffer layer. A gallium nitride channel layer is deposited on this stack, with an aluminum source and a drain contact at either end. The bandgap tuneable p-GaN HEMT includes a two-dimensional molybdenum disulfide layer over the channel, covered by a second AlGaN buffer layer. A p-type gallium nitride cap layer and a platinum gate contact complete the structure. This configuration facilitates bandgap tuning and strain engineering, enhancing electron mobility and density in the two-dimensional electron gas region, making it suitable for high-power and high-frequency applications.

Semiconductor device includes a semiconductor layer, an insulating film provided on the semiconductor layer and having an opening formed therein, a gate electrode connected to the semiconductor layer through opening, a protection film covering gate electrode, and a Ni oxide film, wherein the insulating film has a first surface on the semiconductor layer side and a second surface opposite to the first surface, and the gate electrode has a third surface facing the second surface and spaced apart from the second surface and a fourth surface connecting the second surface and the third surface. The gate electrode includes a Ni film constituting the third surface and the fourth surface, and the Ni oxide film covers the Ni film on the third surface and the fourth surface. The protection film covers the third surface and the fourth surface by being placed over Ni oxide film.

A HEMT GaN transistor with a conductive gate including an upper metal region, and a lower semi-conductor region provided to lower current gate leakage. The lower semiconductor region is formed of: a first sub-region that is P-doped and in contact with the metal region, a second sub-region that is P-doped and in contact with the second layer, and an intermediate sub-region arranged between the first sub-region and the second sub-region, the third sub-region being un-doped or unintentionally doped or doped with a low concentration of dopant compared to that of the first sub-region and second sub-region, respectively.

A number of variations may include a method that may include depositing a first layer on a first semiconductor layer in an overlying position with respect to at least one trench structure formed in the first semiconductor epi layer. The first layer may include a first metal and a second metal. A second layer may comprise a material constructed and arranged to scavenge semiconductor material migrating from the first semiconductor layer during annealing may be deposited over the first layer. The first semiconductor layer may be subjected to at least a first annealing act to provide a first structure. At least a portion of the first structure may be stripped to remove any of the first layer not reacted with the semiconductor material to form a Schottky barrier structure during the first annealing act.

A Method for producing a layer of strained semiconductor material, the method comprising steps for: a) formation on a substrate of a stack comprising a first semiconductor layer based on a first semiconductor material coated with a second semiconductor layer based on a second semiconductor material having a different lattice parameter to that of the first semiconductor material, b) producing on the second semiconductor layer a mask having a symmetry, c) rendering amorphous the first semiconductor layer along with zones of the second semiconductor layer without rendering amorphous one or a plurality of regions of the second semiconductor layer protected by the mask and arranged respectively opposite the masking block(s) d) performing recrystallisation of the regions rendered amorphous and the first semiconductor layer resulting in this first semiconductor layer being strained (FIG. 1A).