A crystalline IZTO oxide semiconductor and a thin film transistor having the same are provided. The thin film transistor includes a gate electrode, a crystalline InZnSn oxide (IZTO) channel layer overlapping the upper or lower portions of the gate electrode and having hexagonal crystal grains, and a gate insulating layer disposed between the gate electrode and the IZTO channel layer, and source and drain electrodes respectively connected to both ends of the IZTO channel layer.

Devices and/or methods of fabrication facilitating suppression of embedded SiGe optical waveguides with low defectivity are provided. In an embodiment, a device can comprise a substrate comprising a trench within the substrate, wherein the trench comprises a base surface and sidewalls comprising the substrate; and a fully strained silicon-germanium (SiGe) structure located within the trench, wherein a bottom surface of the SiGe structure is in contact with the base surface, wherein side surfaces of the SiGe structure are in contact with the sidewalls, and wherein the SiGe structure is at least twice the critical thickness.

Provided are a crack-free laminated film and a structure including this laminated film. This laminated film includes: a buffer layer; and at least one layer of gallium nitride base film disposed on the buffer layer. Moreover, the compression stress of the entire laminated film is 2.0 to 5.0 GPa.

Deep trench isolation structures for high voltage semiconductor-on-insulator devices are disclosed herein. An exemplary deep trench isolation structure surrounds an active region of a semiconductor-on-insulator substrate. The deep trench isolation structure includes a first insulator sidewall spacer, a second insulator sidewall spacer, and a multilayer silicon-comprising isolation structure disposed between the first insulator sidewall spacer and the second insulator sidewall spacer. The multilayer silicon-comprising isolation structure includes a top polysilicon portion disposed over a bottom silicon portion. The bottom polysilicon portion is formed by a selective deposition process, while the top polysilicon portion is formed by a non-selective deposition process. In some embodiments, the bottom silicon portion is doped with boron.

A method for growing a III-V material may include forming at least one layer on a stack including a crystalline layer made of III-V material, a first masking layer surmounting the germination layer, the first masking layer having at least one first opening; depositing a second masking layer covering an upper face of the sacrificial layer; forming at least one second opening in the second masking layer; removing the sacrificial layer selectively at the first masking layer and at the second masking layer; epitaxially growing a material made of the III-V material from the germination layer; forming al least one third opening in the second masking layer; and epitaxially growing at least one material made of the III-V material from the first epitaxial layer.

Provided are high quality metal-nitride, such as aluminum nitride (AlN), films for heat dissipation and heat spreading applications, methods of preparing the same, and deposition of high thermal conductivity heat spreading layers for use in RF devices such as power amplifiers, high electron mobility transistors, etc. Aspects of the inventive concept can be used to enable heterogeneously integrated compound semiconductor on silicon devices or can be used in in non-RF applications as the power densities of these highly scaled microelectronic devices continues to increase.

A method for manufacturing a silicon substrate for a quantum computer, the method includes the steps of forming a Si epitaxial layer by epitaxial growth using a Si source gas as a silicon-based raw material gas, in which a total content of 28Si and 30Si in a whole silicon contained in the silicon-based raw material gas is 99.9% or more, on a silicon substrate, forming an oxygen (O) -doped layer by oxidizing a surface of the Si epitaxial layer, and forming a Si epitaxial layer by epitaxial growth using a Si source gas, in which a total content of 28Si and 30Si in a whole silicon contained in the silicon-based raw material gas is 99.9% or more, on the -doped layer.

The present invention provides a semiconductor structure comprising: a silicon substrate in [100] orientation; a scandium oxide layer over the substrate, in [111] orientation; and a scandium-rare earth-oxide layer over the scandium oxide layer. The scandium-rare earth-oxide layer can have a graded composition to transition lattice constant to match to a subsequent layer, such as an indium nitride layer having very high electron drift velocity. InN over Si (100) offers transistors, photonics and passive electronics that operate in the terahertz frequency range.

Solar cell structures comprising a plurality of solar cells, wherein each solar cell is separated from adjacent solar cell via a tunnel junction and/or a resonant tunneling structure (RTS), are described. Solar cells are implemented on Ge, Si, GaN, sapphire, and glass substrates. Each of the plurality of solar cells is at least partially constructed from a cell material which harnesses photons having energies in a predetermined energy range. In one embodiment each solar cell comprises of at least two sub-cells. It also describes a nano-patterned region/layer to implement high efficiency tandem/multi-junction solar cells that reduces dislocation density due to mismatch in lattice constants in the case of single crystalline and/or polycrystalline solar cells. Finally, solar structure could be used as light-emitting diodes when biased in forward biasing mode. The mode of operation could be determined by a programmed microprocessor.

An IGZO thin-film transistor and a method for manufacturing same. The method includes: acquiring a substrate; forming an IGZO layer on the substrate by a solution process; doping V impurities on a surface of the IGZO layer by a spin doping process; forming a source electrode at one side of the IGZO layer, and forming a drain electrode at the other side; forming a gate dielectric layer on the doped IGZO layer; and forming a gate electrode on the gate dielectric layer.