There is provided a technique that includes: (a) forming a base film, which has a reactivity with a film-forming inhibitor higher than a reactivity between the film-forming inhibitor and an inner surface of a concave portion formed on a surface of a substrate, at least in an upper portion in the concave portion by supplying a pre-treatment gas to the substrate; (b) forming a film-forming inhibition layer on a portion of a surface of the base film, which is formed in the upper portion in the concave portion, by supplying the film-forming inhibitor to the substrate; and (c) growing a film starting from a portion in the concave portion where the film-forming inhibition layer is not formed, by supplying a film-forming gas to the substrate.

Some embodiments of the present disclosure provide a technique capable of reducing an amount of deposits on a back surface of a rotary table. According to one aspect thereof, there is provided a technique that includes: a process chamber provided with process regions; a rotary table configured to rotate a substrate about a point outside the substrate such that the substrate sequentially passes through the process regions; and a rotator configured to rotate the rotary table, wherein the process regions include: a first region in which a process gas is supplied; and a second region in which an inert gas is supplied, and wherein a space corresponding to the second region below the rotary table is configured such that a pressure at the space corresponding to the second region below the rotary table is higher than a pressure at a space corresponding to the first region below the rotary table.

A method of manufacturing a semiconductor element according to the present disclosure includes a mask forming step of defining, on a first surface of a substrate, a front surface region not covered by a first deposition inhibiting mask as a first crystal growth region, an element forming step of forming a semiconductor layer over the first crystal growth region, a mask removing step of removing the mask, and an element separating step of separating the semiconductor layer. After the element separating step, a substrate reusing process is performed one or more times, the substrate reusing process including a mask reforming step of forming a second deposition inhibiting mask in a region differing from a formation position of the first deposition inhibiting mask to expose a second crystal growth region not covered by the mask, an element reforming step of forming a semiconductor layer to serve as an element on the second crystal growth region, a mask removing step of removing the deposition inhibiting mask, and an element separating step of separating the semiconductor layer from the substrate.

A SiC epitaxial growth apparatus according to an embodiment includes: a chamber into which a process gas at least containing silicon and carbon is introduced and housing a substrate to undergo epitaxial growth with the process gas; piping that discharges a gas containing a byproduct generated through epitaxial growth from the chamber; and a valve for pressure control in a middle of the piping. The valve has a flow inlet into which the gas flows from an upstream portion of the piping that causes the chamber and the valve to connect, and a flow outlet that allows the gas to flow out to a downstream portion of the piping that connects with the upstream portion via the valve. a part of the downstream portion is at a position lower than the flow outlet. The apparatus comprises a trap part being capable of collecting the byproduct at the downstream portion.

A method of manufacturing a nitride semiconductor light-emitting element includes: growing an n-side superlattice layer that includes InGaN layers and GaN layers; and, after the step of growing the n-side superlattice layer, growing a light-emitting layer. The step of growing the n-side superlattice layer comprises repeating a cycle n times (n is a number of repetition), the cycle including growing one InGaN layer and growing one GaN layer. In the step of growing the n-side superlattice layer, the step of growing one GaN layer in each cycle from a first cycle to an mth cycle is performed using carrier gas that contains N.sub.2 gas and does not contain H.sub.2 gas. The step of growing one GaN layer in each cycle from a (m+1)th cycle to an nth cycle is performed using gas containing H.sub.2 gas as the carrier gas.

A substrate processing apparatus that places a substrate on a placing portion and performs a heating processing on the substrate includes a plurality of heating control regions that are set plurally along a circumferential direction of the placing portion to heat the substrate placed on the placing portion, and are independently controlled in temperature, and an adjusting unit that adjusts a relative direction of a circumferential direction of the substrate with respect to an arrangement of the circumferential direction of the plurality of heating control regions based on information on deformation of the substrate different in height from a plane orthogonal to a center axis of the substrate in the circumferential direction.

A vapor phase epitaxial growth device comprises a reactor vessel. The device comprises a wafer holder arranged in the reactor vessel. The device comprises a first material gas supply pipe configured to supply first material gas to the reactor vessel. The device comprises a second material gas supply pipe configured to supply second material gas, which is to react with the first material gas, to the reactor vessel. The device comprises a particular gas supply pipe having a solid unit arranged on a supply passage. The device comprises a first heater unit configured to heat the solid unit to a predetermined temperature or higher. The solid unit comprises a mother region and a first region arranged continuously within the mother region. The mother region is a region that does not decompose at the predetermined temperature. The first region is a region that decomposes at the predetermined temperature and contains Mg.

Disclosed herein is a new and improved system and method for fabricating monolithically integrated diamond semiconductor. The method may include the steps of seeding the surface of a substrate material, forming a diamond layer upon the surface of the substrate material; and forming a semiconductor layer within the diamond layer, wherein the diamond semiconductor of the semiconductor layer has n-type donor atoms and a diamond lattice, wherein the donor atoms contribute conduction electrons with mobility greater than 770 cm.sup.2/Vs to the diamond lattice at 100 kPa and 300K, and Wherein the n-type donor atoms are introduced to the lattice through ion tracks.

An epitaxial silicon carbide single crystal wafer having a small depth of shallow pits and having a high quality silicon carbide single crystal thin film and a method for producing the same are provided. The epitaxial silicon carbide single crystal wafer according to the present invention is produced by forming a buffer layer made of a silicon carbide epitaxial film having a thickness of 1 μm or more and 10 μm or less by adjusting the ratio of the number of carbon to that of silicon (C/Si ratio) contained in a silicon-based and carbon-based material gas to 0.5 or more and 1.0 or less, and then by forming a drift layer made of a silicon carbide epitaxial film at a growth rate of 15 μm or more and 100 μm or less per hour. According to the present invention, the depth of the shallow pits observed on the surface of the drift layer can be set at 30 nm or less.

Provided is a technique for manufacturing a nitride semiconductor substrate with which it is possible to manufacture a nitride semiconductor substrate having sufficiently reduced dislocation density with a large area even if manufactured on an inexpensive substrate made of sapphire, etc. A nitride semiconductor substrate in which a nitride semiconductor layer formed on a substrate is formed by laminating an undoped nitride layer and a rare earth element-added nitride layer to which a rare earth element is added as a doping material, and the dislocation density is of the order of 106 cm−2 or less. A method for manufacturing a nitride semiconductor substrate in which a step for growing GaN, InN, AlN, or a mixed crystal of two or more thereof on a substrate to form an undoped nitride layer, and a step for forming a rare earth element-added nitride layer to which a rare earth element is added so as to be substituted for Ga, In, or Al are performed via a series of formation steps using an organic metal vapor epitaxial technique at a temperature of 900 to 1200° C. without extraction from a reaction vessel.