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.

A method for producing an aluminium nitride (AlN)-based layer on a structure with the basis of silicon (Si) or with the basis of a III-V material, may include several deposition cycles performed in a plasma reactor comprising a reaction chamber inside which is disposed a substrate having the structure. Each deposition cycle may include at least the following: deposition of aluminium-based species on an exposed surface of the structure, the deposition including at least one injection into the reaction chamber of an aluminium (Al)-based precursor; and nitridation of the exposed surface of the structure, the nitridation including at least one injection into the reaction chamber of a nitrogen (N)-based precursor and the formation in the reaction chamber of a nitrogen-based plasma. During the formation of the nitrogen-based plasma, a non-zero polarisation voltage V.sub.bias_.sub.substrate may be applied to the substrate.

A novel deposition method of a metal oxide is provided. The deposition method includes a first step of supplying a first precursor to a chamber; a second step of supplying a second precursor to the chamber; a third step of supplying a third precursor to the chamber; and a fourth step of introducing an oxidizer into the chamber after the first step, the second step, and the third step. The first to third precursors are different kinds of precursors, and a substrate placed in the chamber in the first to fourth steps is heated to a temperature higher than or equal to 300° C. and lower than or equal to decomposition temperatures of the first to third precursors.

Disclosed herein methods of forming an Al—Ga containing film comprising: a) exposing a substrate comprising a β-Ga.sub.2O.sub.3, wherein the substrate has a (100) or (−201) orientation, to a vapor phase comprising an aluminum precursor and a gallium precursor; and b) forming a β-(Al.sub.xGa.sub.1-x).sub.2O.sub.3 thin film by a chemical vapor deposition at predetermined conditions and wherein x is 0.01≤x≤0.7. Also disclosed herein are devices comprising the inventive films.

Implementations of the present disclosure generally relate to the fabrication of integrated circuits. More specifically, implementations disclosed herein relate to apparatus, systems, and methods for reducing substrate outgassing. A substrate is processed in an epitaxial deposition chamber for depositing an arsenic-containing material on a substrate and then transferred to a degassing chamber for reducing arsenic outgassing on the substrate. The degassing chamber includes a gas panel for supplying hydrogen, nitrogen, and oxygen and hydrogen chloride or chlorine gas to the chamber, a substrate support, a pump, and at least one heating mechanism. Residual or fugitive arsenic is removed from the substrate such that the substrate may be removed from the degassing chamber without dispersing arsenic into the ambient environment.

A vapor phase growth method of embodiments includes: forming a first silicon carbide layer having a first doping concentration on a silicon carbide substrate at a first growth rate by supplying a first process gas under a first gas condition; forming a second silicon carbide layer having a second doping concentration at a second growth rate higher than the first growth rate by supplying a second process gas under a second gas condition; and forming a third silicon carbide layer having a third doping concentration lower than the first doping concentration and the second doping concentration at a third growth rate higher than the second growth rate by supplying a third process gas under a third gas condition.

A vapor phase growth system includes a process chamber that includes a susceptor lifting mechanism that raises and lowers the susceptor between a first position and a second position. With the susceptor in the first position, the top surface of the susceptor is above the bottom surface of the preheating ring, and a source gas distribution space with a predetermined height dimension is secured between the top surface of the susceptor and the bottom surface of a ceiling plate of the reaction vessel body. With the susceptor in the second position, the top surface of the susceptor is located below the bottom surface of a preheating ring, and a substrate loading/unloading space, which has a greater height dimension than that of the source gas distribution space, is secured between the top surface of the susceptor and the bottom surface of the preheating ring.

A reactor system may comprise a first reaction chamber and a second reaction chamber. The first and second reaction chambers may each comprise a reaction space enclosed therein, a susceptor disposed within the reaction space, and a fluid distribution system in fluid communication with the reaction space. The susceptor in each reaction chamber may be configured to support a substrate. The reactor system may further comprise a first reactant source, wherein the first reaction chamber and the second reaction chamber are fluidly coupled to the first reactant source at least partially by a first reactant shared line. The reactor system may be configured to deliver a first reactant from the first reactant source to the first reaction chamber and a second reaction chamber through the first reactant shared line.

The present invention relates to a Ga.sub.2O.sub.3 crystal film deposition method according to HVPE, a deposition apparatus, and a Ga.sub.2O.sub.3 crystal film-deposited substrate using the same. According to an embodiment of the present invention, a Ga.sub.2O.sub.3 crystal film deposition method, which includes a first step of supplying GaCl gas onto a single-crystal semiconductor substrate via a central supply channel and a second step of supplying oxygen and HCl gas onto the single-crystal semiconductor substrate onto which the GaCl gas is supplied, is provided.

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.