An object of the present invention is to provide a novel technique capable of suppressing the occurrence of cracks in the growth layer.

The present invention is a method for manufacturing a semiconductor substrate, which includes: an embrittlement processing step S10 of reducing strength of an underlying substrate 10; and a crystal growth step S20 of forming the growth layer 20 on the underlying substrate 10. In addition, the present invention is a method for suppressing the occurrence of cracks in the growth layer 20, and this method includes an embrittlement processing step S10 of reducing the strength of the underlying substrate 10 before forming the growth layer 20 on the underlying substrate 10.

An MOCVD system for growing a semiconductor layer on a substrate is provided. The MOCVD system includes an MOCVD growth chamber defined by a jacket having an interior surface and an exterior surface; a water flow chamber surrounding an exterior surface of the jacket of the MOCVD growth chamber; an electronic control system, wherein the electronic control system facilitates pulsed growth of the semiconductor layer; a supply tube comprising a head formed from a hollow structure defining a fitting end and an opposite, shower end, wherein the fitting end has an initial diameter that is less than a diameter at the shower end; and a susceptor configured to hold the substrate and facing the shower end of the supply tube, wherein the MOCVD system operates at a temperature greater than or equal to 1500° C.

An interface including roughness components for improving the propagation of radiation through the interface is provided. The interface includes a first profiled surface of a first layer comprising a set of large roughness components providing a first variation of the first profiled surface having a first characteristic scale and a second profiled surface of a second layer comprising a set of small roughness components providing a second variation of the second profiled surface having a second characteristic scale. The first characteristic scale is approximately an order of magnitude larger than the second characteristic scale. The surfaces can be bonded together using a bonding material, and a filler material also can be present in the interface.

The present disclosure provides a film forming method and an aluminum nitride film forming method for a semiconductor device. The film forming method for a semiconductor device includes performing multiple sputtering routes sequentially. Each sputtering routes includes: loading a substrate into a chamber; moving a shielding plate between a target and the substrate; introducing an inert gas into the chamber to perform a surface modification process on the target; performing a pre-sputtering to pre-treat a surface of the target; moving the shielding plate away from the substrate, and performing a main sputtering on the substrate to form a film on the substrate; and moving the substrate out of the chamber.

An object of the present invention is to provide a novel technique capable of manufacturing a large-diameter semiconductor substrate.

The present invention is a method for manufacturing a semiconductor substrate including a crystal growth step S30 of forming a growth layer 20 on an underlying substrate 10 having through holes 11. In addition, the present invention is a method for forming a growth layer 20 including the through hole formation step S10 of forming through holes 11 in the underlying substrate 10 before forming the growth layer 20 on a surface of the underlying substrate 10.

A quantum dot manufacturing method comprises (a) dispersing, in a solvent, nano-seed particles whose crystal planes are exposed, and (b) growing semiconductor layers on the exposed crystal planes of the nano-seed particles in the solvent.

The invention provides highly transparent single crystalline AlN layers as device substrates for light emitting diodes in order to improve the output and operational degradation of light emitting devices. The highly transparent single crystalline AlN layers have a refractive index in the a-axis direction in the range of 2.250 to 2.400 and an absorption coefficient less than or equal to 15 cm-1 at a wavelength of 265 nm. The invention also provides a method for growing highly transparent single crystalline AlN layers, the method including the steps of maintaining the amount of Al contained in wall deposits formed in a flow channel of a reactor at a level lower than or equal to 30% of the total amount of aluminum fed into the reactor, and maintaining the wall temperature in the flow channel at less than or equal to 1200° C.

A periodic table Group 13 metal nitride crystals grown with a non-polar or semi-polar principal surface have numerous stacking faults. The purpose of the present invention is to provide a period table Group 13 metal nitride crystal wherein the occurrence of stacking faults of this kind are suppressed. The present invention achieves the foregoing by a periodic table Group 13 metal nitride crystal being characterized in that, in a Qx direction intensity profile that includes a maximum intensity and is derived from an isointensity contour plot obtained by x-ray reciprocal lattice mapping of (100) plane of the periodic table Group 13 metal nitride crystal, a Qx width at 1/300th of peak intensity is 6×10.sup.−4 rlu or less.

An epitaxial substrate for electronic devices, including: a Si-based substrate; an AlN initial layer provided on the Si-based substrate; and a buffer layer provided on the AlN initial layer, wherein the roughness Sa of the surface of the AlN initial layer on the side where the buffer layer is located is 4 nm or more. As a result, an epitaxial substrate for electronic devices, in which V pits in a buffer layer structure can be suppressed and longitudinal leakage current characteristics can be improved when an electronic device is fabricated therewith, is provided.

In various embodiments, single-crystal aluminum nitride boules and substrates have low Urbach energies and/or absorption coefficients at deep-ultraviolet wavelengths. The single-crystal aluminum nitride may function as a platform for the fabrication of light-emitting devices such as light-emitting diodes and lasers.