Abstract: A ZnO-containing semiconductor layer contains Se or S added to ZnO and has an emission peak wavelength of ultraviolet light and an emission peak wavelength of visual light. By combining the ZnO-containing semiconductor layer with phosphor or semiconductor which is excited by the emitted ultraviolet light and emits visual light, visual light at various wavelengths can be emitted.

Abstract: A ZnO-containing semiconductor layer contains Se added to ZnO and has an emission peak wavelength of ultraviolet light and an emission peak wavelength of visual light. By combining the ZnO-containing semiconductor layer with phosphor or a semiconductor which is excited by the emitted ultraviolet light and emits visual light, visual light at various wavelengths can be emitted.

Abstract: The ohmic contact between a growth substrate and an electrode formed thereon is improved in a zinc oxide-based semiconductor light-emitting device, thereby improving the light-emission efficiency and reliability A step for forming an n-type semiconductor layer, a light-emitting layer, and a p-type semiconductor layer in sequence on a first principal face of a substrate having a composition of MgxZn1-xO (0?x?0.68); a step for forming microcracks in a second principal face of the substrate so as to extend toward an interior of the substrate; a step for carrying out a heat treatment at a temperature of 100° C. or higher; and a step for forming an electrode by depositing a metal material composed of one among Al, a Ga alloy, and an In alloy on the second principal face of the substrate, and forming an electrode in a heat treatment at a temperature of 300° C. to 1000° C. are provided.

Abstract: A manufacture method for a ZnO-based light emitting device, includes the steps of: forming a ZnO-based semiconductor layer of a first conductivity type above a substrate; two-dimensionally growing a first ZnO-based semiconductor layer of a second conductivity type opposite to the first conductivity type above the ZnO-based semiconductor layer of the first conductivity type; and three-dimensionally growing a second ZnO-based semiconductor layer of the second conductivity type on the first ZnO-based semiconductor layer of the second conductivity type.

Abstract: A semiconductor light emitting device manufacture method is provided which can manufacture a semiconductor light emitting device of high quality. A first substrate of an n-type ZnO substrate is prepared. A lamination structure including an optical emission layer made of ZnO based compound semiconductor is formed on the first substrate. A p-side conductive layer is formed on the lamination structure. A first eutectic material layer made of eutectic material is formed on the p-side conductive layer. A second eutectic material layer made of eutectic material is formed on a second substrate. The first and second eutectic material layers are eutectic-bonded to couple the first and second substrates. After the first substrate is optionally thinned, an n-side electrode is formed on a partial surface of the first substrate.

Abstract: A method which has a step of growing a thermostable-state ZnO-based single crystal on a ZnO single crystal substrate at a growth temperature that is equal to or greater than 600° C. and less than 900° C. by using a metalorganic compound containing no oxygen and water vapor based on an MOCVD method.

Abstract: A method which has a low-temperature growth step of growing a buffer layer of a ZnO-based single crystal on the substrate at a growth temperature in the range of 250° C. to 450° C. using a polar oxygen material and a metalorganic compound containing no oxygen; performing a heat treatment of the buffer layer to effect a transition of the buffer layer to a thermostable-state single crystal layer; and a high-temperature growth step of growing the ZnO-based single crystal layer on the thermostable-state single crystal layer at a growth temperature in the range of 600° C. to 900° C. using a polar oxygen material and a metalorganic compound containing no oxygen.

Abstract: A semiconductor light emitting device manufacture method is provided which can manufacture a semiconductor light emitting device of high quality. A first substrate of an n-type ZnO substrate is prepared. A lamination structure including an optical emission layer made of ZnO based compound semiconductor is formed on the first substrate. A p-side conductive layer is formed on the lamination structure. A first eutectic material layer made of eutectic material is formed on the p-side conductive layer. A second eutectic material layer made of eutectic material is formed on a second substrate. The first and second eutectic material layers are eutectic-bonded to couple the first and second substrates. After the first substrate is optionally thinned, an n-side electrode is formed on a partial surface of the first substrate.

Abstract: Disclosed is a method of manufacturing a ZnO-based semiconductor device, the method includes a first metal layer formation step of forming a first metal layer on a p-type ZnO-based semiconductor layer in island-form and/or mesh-form; a heat treatment step of performing heat treatment of the first metal layer and the p-type ZnO-based semiconductor layer under an oxygen-free atmosphere to form a mixture layer comprising elements of the p-type ZnO-based semiconductor layer and the first metal layer at a boundary region therebetween while maintaining a metal phase layer on a surface of the first metal layer; and a second metal layer formation step of forming a second metal layer so as to cover the first metal layer and the exposed portions of the p-type ZnO-based semiconductor layer through openings of the first metal layer.

Abstract: Disclosed is a method of manufacturing a ZnO-based semiconductor device having at least p-type ZnO-based semiconductor layer, which includes a step of forming a contact metal layer on the p-type ZnO-based semiconductor layer wherein the contact metal layer contains at least one of Ni and Cu; and a step of performing heat treatment of the contact metal layer and the p-type ZnO-based semiconductor layer under an oxygen-free atmosphere to form a mixture layer including elements of the p-type ZnO-based semiconductor layer and the contact metal layer at a boundary region therebetween while maintaining a metal phase layer on a surface of the contact metal layer.

Abstract: A light emitting device includes a lower semiconductor layer of a first conductivity type; an optical emission layer formed on said lower semiconductor layer; an upper semiconductor layer of a second conductivity type opposite to said first conductivity type, said upper semiconductor layer being formed on said optical emission layer; a lower side electrode electrically connected to said lower semiconductor layer; and an upper side electrode electrically connected to said upper semiconductor layer, wherein said upper side electrode is formed on said upper semiconductor layer, and said upper semiconductor layer has a mesh pattern defining a plurality of sections each surrounded by said upper side electrode, and wherein at least one dent is disposed in at least one of said sections, said dent having a bottom reaching at least an upper surface of said lower semiconductor layer and having an opening with an upper edge spaced apart from said upper side electrode.

Abstract: A manufacture method for a ZnO based semiconductor device includes the steps of: (a) preparing a ZnO based semiconductor wafer including a ZnO based semiconductor substrate having a wurzeit structure with a +C plane on one surface and a ?C plane on an opposite surface, a first ZnO based semiconductor layer having a first conductivity type epitaxially grown above the +C plane of the ZnO based semiconductor substrate, and a second ZnO based semiconductor layer having a second conductivity type opposite to the first conductivity type epitaxially grown above the first semiconductor layer; and (b) wet-etching the ZnO based semiconductor wafer with acid etching liquid to etch the ?C plane of the ZnO based semiconductor substrate

Abstract: A film forming apparatus is provided that can prevent source gases from reacting together before reaching the substrate being processed in the apparatus, minimize the influence of the radiation heat from the substrate, and make the gas behavior in the reaction chamber better for crystal film formation. The apparatus forms a film on a surface of a heated substrate 5 by causing a first source gas and a second source gas to react together. The apparatus has a processing chamber 1, in which the substrate 5 is placed. The processing chamber 1 is divided into a heating chamber 1a and a reaction chamber 1b by at least the substrate 5 so that the substrate surface can be exposed to the source gases in the reaction chamber 1b. The apparatus further has an exhaust duct 7, through which the exhaust gas can be discharged. The exhaust duct 7 faces the exposed substrate surface and connects with the reaction chamber 1b.

Abstract: A semiconductor device that has excellent characteristics and mass productivity wherein the introduction of defects thereinto at the time of device separation is prevented, and a method for producing the semiconductor device. In particular, there is provided a high-performance semiconductor device having excellent luminous efficiency, longevity and mass productivity; and a method for producing this semiconductor device. The method for producing the semiconductor device has a step of forming, between a substrate comprising zinc oxide (ZnO) and a device operating layer, a defect-blocking layer having a crystal composition that is different from that of the substrate, and a step of forming device dividing grooves to a depth that goes beyond the defect-blocking layer, relative to the device operating layer side surface of the substrate on which the device operating layer is formed.

Abstract: A method includes the steps of, using water vapor and a metalorganic compound not containing oxygen, (a) performing crystal growth at a low growth temperature and at a low growth pressure in the range of 1 kPa to 30 kPa to form a low-temperature grown single-crystal layer; and (b) performing crystal growth at a high growth temperature and at a pressure higher than the low growth pressure to form a high-temperature grown single-crystal layer on the low-temperature grown single-crystal layer.

Abstract: A ZnO-containing semiconductor layer, doped with Se, has an emission peak wavelength in visual light and has a band gap equivalent to a band gap of ZnO.

Abstract: A ZnO-based semiconductor light emitting element includes a ZnO-based semiconductor layer formed on a rectangular sapphire A-plane substrate having a principal surface lying in the A-plane {11-20}. The substrate has a thickness of 50 to 200 ?m and is surrounded by two parallel first side edges forming an angle in a range of 52.7° to 54.7° with respect to the m-axis orthogonal to the c-axis and two parallel second side edges orthogonal to the first side edges. The light emitting element is obtained by: forming, on a surface of the sapphire A-plane substrate opposite to the surface on which the ZnO-based semiconductor layer is formed, first scribed grooves forming an angle in a range of 52.7° to 54.7° with respect to the m-axis and second scribed grooves orthogonal to the first scribed grooves; and breaking the substrate along the first scribed grooves and then along the second scribed grooves.

Abstract: A semiconductor light-emitting device can include a nitride semiconductor light-emitting layer and can supply a current to an entire light-emitting region quickly and efficiently to output high-intensity light. The semiconductor light-emitting device can include: a transparent substrate; a first conductivity type nitride semiconductor layer; a nitride semiconductor light-emitting layer; a second conductivity type nitride semiconductor layer; a notch region that cuts the second conductivity type nitride semiconductor layer and the nitride semiconductor light-emitting layer and exposes the first conductivity type nitride semiconductor layer, to define mesa active regions and a mesa electrode drawing region; an electrode for the first conductivity type; an ohmic electrode for the second conductivity type; and a supporting substrate including connecting members for the first and second conductivity types.

Abstract: A semiconductor light emitting device can have stable electric characteristics and can emit light with high intensity from a substrate surface. The device can include a transparent substrate and a semiconductor layer on the substrate. The semiconductor layer can include a first conductive type semiconductor layer, a luminescent layer, a second conductive type semiconductor layer, and first and second electrodes disposed to make contact with the first and second conductive type semiconductor layers, respectively. The first conductive type semiconductor layer, the luminescent layer, and the second conductive type semiconductor layer can be laminated in order from the side adjacent the substrate. An end face of the semiconductor layer can include a first terrace provided in an end face of the first conductive type semiconductor layer in parallel with the substrate surface, and an inclined end face region provided nearer to the substrate than the first terrace.

Abstract: A ZnO based semiconductor device includes: a lamination structure including a first semiconductor layer containing ZnO based semiconductor of a first conductivity type and a second semiconductor layer containing ZnO based semiconductor of a second conductivity type opposite to the first conductivity type, formed above the first semiconductor layer and forming a pn junction together with the first semiconductor layer; and a Zn—Si—O layer containing compound of Zn, Si and O and covering a surface exposing the pn junction of the lamination structure.