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 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: 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 method for manufacturing a ZnO based compound semiconductor device including a contact for a p-type ZnO based compound semiconductor electrode is provided. The method includes forming a stacked body including a substrate, and an n-type ZnO based semiconductor layer and a p-type ZnO based semiconductor layer on the substrate, with the p-type ZnO based semiconductor layer exposed to outside. The stacked body is subjected to heat treatment so that a surface temperature of the p-type ZnO based semiconductor layer is in the range of 250° C. to 500° C. After the heat treatment, a p-side metal electrode is formed on the p-type ZnO based semiconductor layer at a temperature lower than 550° C. And an n-side metal electrode is formed on the n-type ZnO based semiconductor layer.

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.