Abstract: A semiconductor laser element includes a substrate having a first main surface and a second main surface; a semiconductor layered body including an active layer, the semiconductor layered body being disposed on the first main surface; and a plurality of sub-patterns that, when combined, form an integrated pattern that allows reading of predetermined information, the plurality of sub-patterns being disposed on either one or both a first main surface side and a second main surface side of the substrate.

Abstract: A semiconductor laser element includes a substrate having a first main surface and a second main surface; a semiconductor layered body including an active layer, the semiconductor layered body being disposed on the first main surface; and a plurality of sub-patterns that, when combined, form an integrated pattern that allows reading of predetermined information, the plurality of sub-patterns being disposed on either one or both a first main surface side and a second main surface side of the substrate.

Abstract: A semiconductor laser element includes a substrate; a semiconductor layer formed on a front surface of the substrate; a first electrode formed on a back surface of the substrate; a second electrode formed on a front surface of the semiconductor layer; and at least one mark configured to allow reading of predetermined information, the at least one mark being formed in at least one of (i) a position on the surface on which the first electrode is formed, spaced apart from the first electrode and (ii) a position on the surface on which the second electrode is formed, spaced apart from the second electrode. The at least one mark is made of a metal material and has a thickness smaller than a thickness of the electrode that is formed on the surface on which the at least one mark is formed.

Abstract: A semiconductor laser element includes a substrate; a semiconductor layer formed on a front surface of the substrate; a first electrode formed on a back surface of the substrate; a second electrode formed on a front surface of the semiconductor layer; and at least one mark configured to allow reading of predetermined information, the at least one mark being formed in at least one of (i) a position on the surface on which the first electrode is formed, spaced apart from the first electrode and (ii) a position on the surface on which the second electrode is formed, spaced apart from the second electrode. The at least one mark is made of a metal material and has a thickness smaller than a thickness of the electrode that is formed on the surface on which the at least one mark is formed.

Abstract: A method for manufacturing a nitride semiconductor laser element has: (a) forming a nitride semiconductor layer on a substrate; (b) forming a ridge on a surface of the nitride semiconductor; (c) forming a first protective film on the nitride semiconductor layer including the ridge; (d) removing the first protective film from at least a top face of the ridge; (e) forming a conductive layer composed of a two or more of multilayer film with different compositions on the first protective film and the nitride semiconductor layer including the ridge, and introducing a gap at locations of at least at the uppermost conductive layer corresponding to the base portion from the ridge shoulders; and (f) removing part of the conductive layer through a gap to form a void defined by the first protective film and the conductive layer at least on the ridge base portions.

Abstract: A method for manufacturing a nitride semiconductor laser element has: (a) forming a nitride semiconductor layer on a substrate; (b) forming a ridge on a surface of the nitride semiconductor; (c) forming a first protective film on the nitride semiconductor layer including the ridge; (d) removing the first protective film from at least a top face of the ridge; (e) forming a conductive layer composed of a two or more of multilayer film with different compositions on the first protective film and the nitride semiconductor layer including the ridge, and introducing a gap at locations of at least at the uppermost conductive layer corresponding to the base portion from the ridge shoulders; and (f) removing part of the conductive layer through a gap to form a void defined the first protective film and the conductive layer at least on the ridge base portions.

Abstract: A method for manufacturing a nitride semiconductor laser element, equipped with a laminate that has a first conductivity type nitride semiconductor layer, an active layer, and a second conductivity type nitride semiconductor layer on a substrate, and constitutes a resonator, comprises the steps of: forming a first auxiliary groove having an exposed region extending in the resonator direction of the laser element and in which at least the second conductivity type nitride semiconductor layer and the active layer are removed from the second conductivity type nitride semiconductor layer side on both sides in the resonator direction of an element region where the laser element is formed on the surface of the laminate, thereby exposing the first conductivity type nitride semiconductor layer, and two protrusion regions that are narrower than the exposed region and protrude in the resonator direction from the exposed region; forming a second auxiliary groove whose angle of inclination of the side faces with respect t

Abstract: The present invention provides a nitride semiconductor device wherein on a substrate having a first main surface and a second main surface, a nitride semiconductor layer is formed on the first main surface and an electrode is formed on the second main surface, wherein the substrate comprises dislocation concentration regions, and on the dislocation concentration regions on the second main surface of the substrate, the electrode having at least an opening region is formed, and the edge surface of the substrate has a region roughly matching the edge surface of the electrode formed on the dislocation concentration regions. With the present invention, device separation can be stabilized and a nitride semiconductor device is provided having good ohmic contact between a nitride semiconductor layer and electrode.

Abstract: A method for manufacturing a nitride semiconductor laser element, equipped with a laminate that has a first conductivity type nitride semiconductor layer, an active layer, and a second conductivity type nitride semiconductor layer on a substrate, and constitutes a resonator, comprises the steps of: forming a first auxiliary groove having an exposed region extending in the resonator direction of the laser element and in which at least the second conductivity type nitride semiconductor layer and the active layer are removed from the second conductivity type nitride semiconductor layer side on both sides in the resonator direction of an element region where the laser element is formed on the surface of the laminate, thereby exposing the first conductivity type nitride semiconductor layer, and two protrusion regions that are narrower than the exposed region and protrude in the resonator direction from the exposed region; forming a second auxiliary groove whose angle of inclination of the side faces with respect t

Abstract: The present invention provides a nitride semiconductor device wherein on a substrate having a first main surface and a second main surface, a nitride semiconductor layer is formed on the first main surface and an electrode is formed on the second main surface, wherein the substrate comprises dislocation concentration regions, and on the dislocation concentration regions on the second main surface of the substrate, the electrode having at least an opening region is formed, and the edge surface of the substrate has a region roughly matching the edge surface of the electrode formed on the dislocation concentration regions. With the present invention, device separation can be stabilized and a nitride semiconductor device is provided having good ohmic contact between a nitride semiconductor layer and electrode.

Abstract: An opposed terminal structure including a supporting substrate, a first terminal, a nitride semiconductor with a light-emitting layer, and a second terminal. The second terminal forms an opposed terminal structure with the first terminal, which can be formed in a variety of patterns.

Abstract: An opposed terminal structure including a supporting substrate, a first terminal, a nitride semiconductor with a light-emitting layer, and a second terminal. The second terminal forms an opposed terminal structure with the first terminal, which can be formed in a variety of patterns.

Abstract: An opposed terminal structure including a supporting substrate, a first terminal, a nitride semiconductor with a light-emitting layer, and a second terminal. The second terminal forms an opposed terminal structure with the first terminal, which can be formed in a variety of patterns.

Abstract: A method of producing an efficient nitride semiconductor element having an opposed terminal structure. The method includes a growing step for growing the nitride semiconductor further having an undoped GaN layer on a different materials substrate; subsequently, an attaching step for attaching the supporting substrate to the first conductive type nitride semiconductor layer side of the nitride semiconductor and interposing a first terminal between them; and subsequently, an exposing step for exposing the second conductive type nitride semiconductor layer by eliminating the different material substrate and the undoped GaN.

Abstract: An opposed terminal structure including a supporting substrate, a first terminal, a nitride semiconductor with a light-emitting layer, and a second terminal. The second terminal forms an opposed terminal structure with the first terminal, which can be formed in a variety of patterns.

Abstract: The present invention provides a high efficient nitride semiconductor element having an opposed terminal structure, whose terminals facing each other, and a method for producing thereof.

Abstract: A highly efficient nitride semiconductor element having an opposed terminal structure, whose terminals face each other. The nitride semiconductor element includes a conductive layer, a first terminal, a nitride semiconductor with a light-emitting layer, and a second terminal, on a supporting substrate successively. The first terminal and a first insulating protect layer are interposed between the conductive layer and a first conductive type nitride semiconductor layer of the nitride semiconductor.

Abstract: The present invention provides a high efficient nitride semiconductor element having an opposed terminal structure, whose terminals facing each other, and a method for producing thereof.

Abstract: A recycling automatic document feeder (RADF) for a copier or similar image forming apparatus and capable of preventing curled or otherwise deformed documents from being damaged when such documents are recirculated. The RADF includes a parting plate for separating part of a stack of documents not undergone illumination from the other part undergone illumination and returned to the stack. When the parting plate is raised to a level above a predetermined height, the RADF is inhibited from returning the illuminated documents to the stack.

Abstract: An automatic document feeder (ADF) for use with with a copier, laser printer or similar image recorder and capable of handling a computer form (CF) document in addition to ordinary documents in the form of sheets. The ADF is selectively operable in either one of two different document transport modes, i.e., it transports initial fives pages of a CF document at a speed per page which is lower than an ordinary speed. While the lower transport speed is selected, the operator has a sufficient time to determine in which direction the CF document neatly folds along the perforation intervening between the first and second pages.