Abstract: A substrate W is placed on a support part 7 provided in a reaction chamber 2. While the substrate W is rotated together with the support part 7 around a rotation shaft A passing through a center of the substrate W at a rotating speed of 1300 rpm or more and 2000 rpm or less, a source gas including an organic metal is supplied onto the substrate W from a portion above the reaction chamber 2 to cause a III-V semiconductor layer to grow on the substrate W.

Abstract: A film forming apparatus includes: a support, a rotator, a gas supplier, and a radiation thermometer configured to measure a temperature of a surface of a substrate, wherein the radiation thermometer includes: a light source of an irradiation light to be irradiated to the surface of the substrate; a first light receiver configured to receive a reflected light from a first measurement region at a predetermined distance from the rotation center on the surface of the substrate; and a second light receiver configured to receive a heat radiation light from a second measurement region extending in a rotation direction of the substrate at the predetermined distance from the rotation center on the surface of the substrate.

Abstract: A curvature measurement apparatus according to an embodiment includes: a laser beam emitting portion emitting a laser beam; a first polarization beam splitter separating the emitted laser beam into first and second laser beams in different polarization directions and in different travel directions; a mirror reflecting the first laser beam so that the first and second laser beams travel side by side to a substrate; a second polarization beam splitter transmitting the second laser beam mirror-reflected from the substrate and reflecting the first laser beam, mirror-reflected from the substrate, in a direction different from a travel direction of the second laser beam; a one-dimensional first position detection device detecting an incident position of the reflected first laser beam on the first position detection device; and a one-dimensional second position detection device detecting an incident position of the transmitted second laser beam on the second position detection device.

Abstract: A radiation thermometer has a broadband light source which generates broadband light; an optical filter which, when the broadband light is incident on the measuring target object, passes only light in a predetermined wavelength range of reflected light and heat radiation light from a measuring target object; a light receiver which receives the light in the predetermined wavelength range through the optical filter; and a calculator which calculates a temperature of the measuring target object by using reflected light intensity and heat radiation intensity of the light in the predetermined wavelength range received by the light receiver, wherein an emission spectrum of the broadband light is a spectrum with a full width at half maximum which is equal to or wider than the predetermined wavelength range, and with light intensity increasing while a wavelength thereof becomes longer in the predetermined wavelength range.

Abstract: A curvature measurement apparatus according to an embodiment includes: a laser beam emitting portion emitting a laser beam; a first polarization beam splitter separating the emitted laser beam into first and second laser beams in different polarization directions and in different travel directions; a mirror reflecting the first laser beam so that the first and second laser beams travel side by side to a substrate; a second polarization beam splitter transmitting the second laser beam mirror-reflected from the substrate and reflecting the first laser beam, mirror-reflected from the substrate, in a direction different from a travel direction of the second laser beam; a one-dimensional first position detection device detecting an incident position of the reflected first laser beam on the first position detection device; and a one-dimensional second position detection device detecting an incident position of the transmitted second laser beam on the second position detection device.

Abstract: A chemical vapor deposition apparatus which comprises a susceptor for mounting a substrate thereon, a heater for heating the substrate, a feed gas introduction portion and a reaction gas exhaust portion, wherein a light transmitting ceramics plate held or reinforced by means of a supporting member is equipped between the heater and a mounting position of the substrate. A chemical vapor deposition apparatus that is capable of forming film stably for a long time without giving a negative influence on a quality of semiconductor film even in a case of chemical vapor deposition reaction employing a furiously corrosive gas with an elevated temperature for producing a gallium nitride compound semiconductor or so was realized.

Abstract: A chemical vapor deposition apparatus which comprises a susceptor for mounting a substrate thereon, a heater for heating the substrate, a feed gas introduction portion and a reaction gas exhaust portion, wherein a light transmitting ceramics plate held or reinforced by means of a supporting member is equipped between the heater and a mounting position of the substrate. A chemical vapor deposition apparatus that is capable of forming film stably for a long time without giving a negative influence on a quality of semiconductor film even in a case of chemical vapor deposition reaction employing a furiously corrosive gas with an elevated temperature for producing a gallium nitride compound semiconductor or so was realized.

Abstract: In order to improve light-emission efficiency without degrading protection performance of a light-emitting layer structure a three p-type layer structure composed of first to third layers is provided in contact with a light-emitting layer structure. The first layer is an n-type AlGaN layer that serves as a protective layer, the third layer is a GaN:Mg layer that serves as a contact layer and the second layer is an AlGaN:Mg layer formed between these layers as an intermediate layer. The provision of the intermediate layer enables an InGaN layer to be thoroughly protected from heat during growth of layers above even if the n-type AlGaN layer is made thin, whereby the GaN:Mg layer can be brought near the light-emitting layer structure to enhance the efficiency of hole injection into the light-emitting layer structure and thus increase the light-emission efficiency.

Abstract: A group 3–5 compound semiconductor comprising an interface of two layers having lattice mismatch, an intermediate layer having a film thickness of 25 nm or more and a quantum well layer, in this order. The compound semiconductor has high crystallinity and high quality, and suitably used for a light emitting diode.

Abstract: A chemical vapor deposition apparatus which comprises a susceptor for mounting a substrate thereon, a heater for heating the substrate, a feed gas introduction portion and a reaction gas exhaust portion, wherein a light transmitting ceramics plate held or reinforced by means of a supporting member is equipped between the heater and a mounting position of the substrate. A chemical vapor deposition apparatus that is capable of forming film stably for a long time without giving a negative influence on a quality of semiconductor film even in a case of chemical vapor deposition reaction employing a furiously corrosive gas with an elevated temperature for producing a gallium nitride compound semiconductor or so was realized.

Abstract: In order to improve light-emission efficiency without degrading protection performance of a light-emitting layer structure a three p-type layer structure composed of first to third layers is provided in contact with a light-emitting layer structure. The first layer is an n-type AlGaN layer that serves as a protective layer, the third layer is a GaN:Mg layer that serves as a contact layer and the second layer is an AlGaN:Mg layer formed between these layers as an intermediate layer. The provision of the intermediate layer enables an InGaN layer to be thoroughly protected from heat during growth of layers above even if the n-type AlGaN layer is made thin, whereby the GaN:Mg layer can be brought near the light-emitting layer structure to enhance the efficiency of hole injection into the light-emitting layer structure and thus increase the light-emission efficiency.

Abstract: In order to improve light-emission efficiency without degrading protection performance of a light-emitting layer structure a three p-type layer structure composed of first to third layers is provided in contact with a light-emitting layer structure. The first layer is an n-type AlGaN layer that serves as a protective layer, the third layer is a GaN:Mg layer that serves as a contact layer and the second layer is an AlGaN:Mg layer formed between these layers as an intermediate layer. The provision of the intermediate layer enables an InGaN layer to be thoroughly protected from heat during growth of layers above even if the n-type AlGaN layer is made thin, whereby the GaN:Mg layer can be brought near the light-emitting layer structure to enhance the efficiency of hole injection into the light-emitting layer structure and thus increase the light-emission efficiency.

Abstract: When a crystal layer of III-V Group nitride compound semiconductor is formed, a nitride compound semiconductor layer is first overlaid on a substrate to form a base layer and a III-V Group nitride compound semiconductor represented by the general formula InxGayAlzN (where 0?x?1, 0?y?1, 0?z?1, x+y+z=1) is epitaxially grown on the base layer by hydride vapor phase epitaxy at a deposition pressure of not lower than 800 Torr. By making the deposition pressure not lower than 800 Torr, the crystallinity of the III-V Group nitride compound semiconductor can be markedly improved and its defect density reduced.

Abstract: In a semiconductor manufacturing system for manufacturing compound semiconductor by MOCVD, a lead-in member is provided for guiding feed gas supplied from a feed gas supply unit onto the surface of a semiconductor substrate disposed in a reactor, a main body of the lead-in member is constituted as a hollow member to form a feed gas guide passage for conducting the feed gas in an prescribed direction and is formed with multiple orifices, and the feed gas in the feed gas guide passage is jetted from the orifices in a direction perpendicular to the prescribed direction so that the semiconductor substrate is bathed in a feed gas flow of uniform amount jetted from the lead-in member in this manner. Furthermore, a pressure differential produced between the inner side and outer side of the nozzle member enables the feed gas jetted from the nozzle member to flow over the whole surface of the substrate at a uniform flow rate.

Abstract: Provided is a III-V compound semiconductor having a layer formed from a first III-V compound semiconductor expressed by the general formula InuGavAlwN (where 0?u?1, 0?v?1, 0?w?1, u+v+w=1), a pattern formed on the layer from a material different not only from the first III-V compound semiconductor but also from a second III-V compound semiconductor hereinafter described, and a layer formed on the first III-V compound semiconductor and the pattern from the second III-V compound semiconductor expressed by the general formula InxGayAlzN (where 0?x?1, 0?y?1, 0?x?1, x+y+z=1), wherein the full width at half maximum of the (0004) reflection X-ray rocking curve of the second III-V compound semiconductor is 700 seconds or less regardless of the direction of X-ray incidence. In the III-V compound semiconductor, which is a high quality semiconductor, the occurrence of low angle grain boundaries is suppressed.

Abstract: Provide is a 3-5 group compound semiconductor having a concentration of a p-type dopant of 1×1017 cm− or more and 1×1021 cm−3 or less, which can be laminated to control the carrier concentration of an InGaAlN-type mixed crystal in a low range with high reproducibility. Also provided is a 3-5 group compound semiconductor in which the carrier concentration of an InGaAlN-type mixed crystal is controlled in a low range with high reproducibility, and a light emitting device having high light emitting efficiency.

Abstract: A method for fabricating a GaN-based III-V Group compound semiconductor is provided that utilizes a regrowth method based on the HVPE method to form a second III-V Group compound semiconductor layer having a flat surface on a first III-V Group compound semiconductor layer formed with a mask layer. The method uses a mixed carrier gas of hydrogen gas and nitrogen gas to control formation of a facet group including at least the {33-62} facet by the regrowth, and conducting the regrowth until a plane parallel to the surface of the first III-V Group compound semiconductor layer is once annihilated, thereby fabricating a III-V Group compound semiconductor having low dislocation density.

Abstract: In the method of producing the 3-5 group compound semiconductor carrying out the lateral direction selective growth of the desired GaN type 3-5 group compound-semiconductor layer on this c-plane by the stripe mask formed on the c-plane of the underlying crystal containing a GaN type 3-5 group compound semiconductor, a stripe mask is formed on the underlying crystal such that the direction of the stripe is rotated 0.095° or more and less than 9.6° from <1-100> direction, and with using this stripe mask, the lateral direction selective growth of the GaN type 3-5 group compound-semiconductor layer is carried out, and a high quality 3-5 group compound-semiconductor layer can be formed on the underlying crystal.

Abstract: In order to improve light-emission efficiency without degrading protection performance of a light-emitting layer structure a three p-type layer structure composed of first to third layers is provided in contact with a light-emitting layer structure. The first layer is an n-type AlGaN layer that serves as a protective layer, the third layer is a GaN:Mg layer that serves as a contact layer and the second layer is an AlGaN:Mg layer formed between these layers as an intermediate layer. The provision of the intermediate layer enables an InGaN layer to be thoroughly protected from heat during growth of layers above even if the n-type AlGaN layer is made thin, whereby the GaN:Mg layer can be brought near the light-emitting layer structure to enhance the efficiency of hole injection into the light-emitting layer structure and thus increase the light-emission efficiency.

Abstract: When a crystal layer of III-V Group nitride compound semiconductor is formed, a nitride compound semiconductor layer is first overlaid on a substrate to form a base layer and a III-V Group nitride compound semiconductor represented by the general formula InxGayAlzN (where 0≦x≦1, 0≦y≦1, 0≦z≦1, x+y+z=1) is epitaxially grown on the base layer by hydride vapor phase epitaxy at a deposition pressure of not lower than 800 Torr. By making the deposition pressure not lower than 800 Torr, the crystallinity of the III-V Group nitride compound semiconductor can be markedly improved and its defect density reduced.