Disclosed herein is the controlled epitaxy of Al.sub.xGa.sub.1-xAs, Al.sub.xIn.sub.1-xP, and Al.sub.xGa.sub.yIn.sub.1-x-yP by hydride vapor phase epitaxy (HVPE) through use of an external AlCl.sub.3 generator.

Disclosed herein is the controlled epitaxy of Al.sub.xGa.sub.1-xAs, Al.sub.xIn.sub.1-xP, and Al.sub.xGa.sub.yIn.sub.1-x-yP by hydride vapor phase epitaxy (HVPE) through use of an external AlCl.sub.3 generator.

A growth device and method for low-stress crystals are provided, which relate to the field of preparation of crystals, in particular to a device and method for preparing low-stress and low-defect crystals by using a pulling method. The growth device includes a furnace body; a crucible and a heating and insulation system which are arranged at a bottom of the furnace body; a crystal pulling mechanism, and a quartz observation window; the device further includes a liftable heating mantle mechanism including a heating mantle body, a heating mantle supporting component, a heating wire arranged around the heating mantle body, and a heating mantle lifting mechanism. The method includes: after crystals are pulled out of a melt, covering the crystals with a liftable heating mantle mechanism. By the use of the present invention, a temperature gradient inside the crystals in a crystal growth process and in a cooling process after the crystals are pulled can be reduced, thereby reducing the crystal stress, reducing defects, and avoiding the crystals from being cracked; and at the same time, the temperature gradient in the melt is maintained, thereby guaranteeing a stable crystal growth process and ensuring the yield of the crystals.

An AlN monocrystal plate disclosed herein may include: a first surface in a thickness direction; and a second surface opposing the first surface. A metal component containing region may be disposed substantially parallel to the first surface in an intermediate portion between the first surface and the second surface. In the metal component containing region, a plurality of metal components may be introduced and distributed. A type of the metal components may be Ga.

A group III-nitride laminated substrate includes a sapphire substrate, a first layer that is formed on the sapphire substrate and is made of aluminum nitride, a second layer that is formed on the first layer and serves as an n-type layer made of gallium nitride and doped with an n-type dopant, a third layer that is formed on the second layer and serves as a light-emitting layer made of a group III-nitride, and a fourth layer that is formed on the third layer and serves as a p-type layer made of a group III-nitride and doped with a p-type dopant. The second layer has a thickness of 7 μm or less. A half-value width of (0002) diffraction determined through X-ray rocking curve analysis is 100 seconds or less, and a half-value width of (10-12) diffraction determined through X-ray rocking curve analysis is 200 seconds or less.

An object is to provide a nonpolar or semipolar GaN substrate having improved size and crystal quality. A self-standing GaN substrate has an angle between the normal of the principal surface and an m-axis of 0 degrees or more and 20 degrees or less, wherein: the size of the projected image in a c-axis direction when the principal surface is vertically projected on an M-plane is 10 mm or more; and when an a-axis length is measured on an intersection line between the principal surface and an A-plane, a low distortion section with a section length of 6 mm or more and with an a-axis length variation within the section of 10.0×10.sup.−5 Å or less is observed.

According to the present invention, there is provided a group III nitride semiconductor substrate (free-standing substrate 30) that is formed of group III nitride semiconductor crystals. Both exposed first and second main surfaces in a relationship of top and bottom are semipolar planes. A variation coefficient of an emission wavelength of each of the first and second main surfaces, which is calculated by dividing a standard deviation of an emission wavelength by an average value of the emission wavelength, is 0.05% or less in photoluminescence (PL) measurement in which mapping is performed in units of an area of 1 mm.sup.2 by emitting helium-cadmium (He—Cd) laser, which has a wavelength of 325 nm and an output of 10 mW or more and 40 mW or less, at room temperature. In a case where devices are manufactured over the free-standing substrate 30, variations in quality among the devices are suppressed.

High quality ammonothermal group III metal nitride crystals having a pattern of locally-approximately-linear arrays of threading dislocations, methods of manufacturing high quality ammonothermal group III metal nitride crystals, and methods of using such crystals are disclosed. The crystals are useful for seed bulk crystal growth and as substrates for light emitting diodes, laser diodes, transistors, photodetectors, solar cells, and for photoelectrochemical water splitting for hydrogen generation devices.

Hydride phase vapor epitaxy (HVPE) growth apparatus, methods and materials and structures grown thereby. An HVPE reactor includes generation, accumulation, and growth zones. A source material for growth of indium nitride is generated and collected inside the reactor. A first reactive gas reacts with an indium source inside the generation zone to produce a first gas product having an indium-containing compound. The first gas product is cooled and condenses into a liquid or solid condensate or source material having an indium-containing compound. The source material is collected in the accumulation zone. Vapor or gas resulting from evaporation of the condensate forms a second gas product, which reacts with a second reactive gas in the growth zone for growth of indium nitride.

The problem to be solved by the present invention is to provide novel technology capable of suppressing the introduction of displacement to a growth layer. The present invention, which solves the abovementioned problem, pertains to a method for manufacturing a semiconductor substrate, the method including: a processing step for removing a portion of a base substrate and forming a pattern that includes a minor angle; and a crystal growth step for forming a growth layer on the base substrate where the patter has been formed. In addition, the present invention pertains to a method for suppressing the introduction of displacement to a growth layer, the method including a processing step for removing a portion of the base substrate and forming a pattern that includes a minor angle prior to forming the growth layer on the base substrate.