Abstract: A nitride-based semiconductor light-emitting device capable of suppressing complication of a manufacturing process and reduction of luminous efficiency is obtained. This nitride-based semiconductor light-emitting device (50) includes a nitride-based semiconductor device layer (23) formed on a main surface of a (1-100) plane of a substrate (21), having a light-emitting layer (26) having a main surface of a (1-100) plane, a facet (50a) formed on an end of a region including the light-emitting layer (26) of the nitride-based semiconductor device layer (23), formed by a (000-1) plane extending in a direction substantially perpendicular to the main surface ((1-100) plane) of the light-emitting layer (26), and a reflection surface (50c) formed on a region opposed to the facet (50a) of the (000-1) plane, formed by a growth surface of the nitride-based semiconductor device layer (23), extending in a direction inclined at an angle ?1 (about) 62° with respect to the facet (50a).

Abstract: Provided is a semiconductor element which can suppress deterioration of element characteristics even when a semiconductor element section includes a plurality of directions having different thermal expansion coefficients within an in-plane direction. A semiconductor laser element (the semiconductor element) is provided with the semiconductor element section, which includes a direction of [1-100] and a direction of [0001] having different thermal expansion coefficients within the in-plane direction of a main surface, and a sub-mount, which includes an arrow (E) direction and an arrow (F) direction having different thermal expansion coefficients within the in-plane direction of the main surface. The semiconductor element section is bonded on the sub-mount so that the direction [1-100] of the semiconductor element section is close to the side of the arrow (E) direction than the arrow (F) direction of the sub-mount.

Abstract: A blue-violet semiconductor laser device has a first p-electrode formed on its upper surface and a first n-electrode formed on its lower surface. A red semiconductor laser device has a second n-electrode formed on its upper surface and a second p-electrode formed on its lower surface. An infrared semiconductor laser device has a third n-electrode formed on its upper surface and a third p-electrode formed on its lower surface. Solder films are partially formed on the upper surface of the first p-electrode in the blue-violet semiconductor laser device. Two of the solder films are formed with a predetermined distance between them on the upper surface of the first p-electrode. This results in a portion of the first p-electrode being exposed. The first, second and third p-electrodes of the blue-violet semiconductor laser device, red semiconductor laser device, and infrared semiconductor laser device are common electrodes.

Abstract: A nitride-based semiconductor device includes a substrate made of a nitride-based semiconductor, a device layer formed on the substrate, and an electrode formed on a surface of the substrate opposite to the device layer. The substrate includes a first surface having a nonpolar plane or a semipolar plane, a second surface opposite to the first surface, a defect concentration region extending in a direction inclined with respect to a normal direction of the first surface from the first surface toward the second surface and penetrating to the second surface and a current path region separated from other region of the substrate by the defect concentration region employed as a boundary, the defect concentration region is not exposed on the first surface, and the electrode is formed on the second surface in the current path region.

Abstract: Improving the lifetime of an integrated semiconductor laser diode module into which a GaN semiconductor laser diode and a GaP semiconductor laser diode are integrated, and the lasing properties of the laser diodes. Prior to a joining step of an LD 1 wafer that is made of a nitride semiconductor structure formed on a GaN substrate and an LD 2 wafer that is made of an aluminum gallium indium phosphide semiconductor structure, a facet of a resonator of the nitride semiconductor structure is formed by etching. A facet of a resonator of the aluminum gallium indium phosphide semiconductor structure is formed, after the joining step, by cleaving. The wafers are joined so that the facets of the resonators of the nitride semiconductor structure and aluminum gallium indium phosphide semiconductor structure are out of alignment in a lengthwise direction of the resonators.

Abstract: Illumination device has a plurality of light emitting units, each with light emitting element and first fluorescent material region provided at a light emitting side of the light emitting element. A plurality of second fluorescent material regions are provided at the light emitting sides of respective light emitting units. Second fluorescent material regions having the same emission conversion property are respectively provided at the light emitting side of at least one light emitting unit having the same emission property among the plurality of light emitting units.

Abstract: A method of manufacturing a semiconductor laser device comprises steps of forming a first semiconductor laser device substrate having first grooves for cleavage on a surface thereof, bonding a second semiconductor laser device substrate onto the surface side having the first grooves and thereafter cleaving the first and second semiconductor laser device substrates along at least the first grooves.

Abstract: A sub-substrate, a blue-violet semiconductor laser device, an insulating layer, and a red semiconductor laser device are stacked in order on a support member through a plurality of fusion layers. The insulating layer is stacked on an n-side pad electrode of the blue-violet semiconductor laser device, and a conductive layer is formed on the insulating layer. The red semiconductor laser device is stacked on the conductive layer through a fusion layer. The conductive layer is electrically connected to a p-side pad electrode of the red semiconductor laser device. The n-side pad electrode of the blue-violet semiconductor laser device and the n-side pad electrode of the red semiconductor laser device are electrically connected to each other.

Abstract: A laser diode device includes a red laser diode element, a green laser diode element and a blue laser diode element. The red, green and blue laser diode elements are arranged in a single package in a state of being connected to wires for supplying power independently. Additionally, the blue laser diode element is arranged between the red laser diode element and the green laser diode element as viewed from a laser beam-emitting direction.

Abstract: A laser diode device includes a first laser diode element, a second laser diode element and a third laser diode element having a longer lasing wavelength than the first and second 6 laser diode elements. The first, second and third laser diode elements are arranged in a package, and the third laser diode element is not electrically connected to the first and second laser diode elements.

Abstract: A projection and a raised portion are formed on an upper surface of a blue-violet semiconductor laser device. A projection and a raised portion are formed on a lower surface of a red semiconductor laser device. The height of the projection is smaller than the height of the raised portion, and the height of the projection is smaller than the height of the raised portion. The blue-violet semiconductor laser device and the red semiconductor laser device are joined to each other such that the projections are opposed to each other.

Abstract: A first semiconductor laser element is formed on a surface of the first substrate and including a first active layer. A second semiconductor laser element is bonded to the first semiconductor laser element with a first insulating film interposed therebetween. A first electrode is connected to the first semiconductor laser element. A second electrode is arranged on the surface of the first semiconductor laser element with the first insulating film interposed therebetween and connected to the second semiconductor laser element. The first semiconductor laser element has an optical waveguide formed in a region where the second semiconductor laser element is not bonded while the first electrode is arranged on the region, and the second electrode is formed to extend from between the second semiconductor laser element and first insulating film toward the region.

Abstract: A nitride-based semiconductor light-emitting device capable of suppressing reduction of characteristics and a yield and method of fabricating the same is described. The method of fabricating includes the steps of forming a groove portion on a nitride-based semiconductor substrate by selectively removing a prescribed region of a second region of the nitride-based semiconductor substrate other than a first region corresponding to a light-emitting portion of a nitride-based semiconductor layer up to a prescribed depth and forming the nitride-based semiconductor layer having a different composition from the nitride-based semiconductor substrate on the first region and the groove portion of the nitride-based semiconductor substrate.

Abstract: A method of fabricating a nitride-based semiconductor device capable of reducing contact resistance between a nitrogen face of a nitride-based semiconductor substrate or the like and an electrode is provided. This method of fabricating a nitride-based semiconductor device comprises steps of etching the back surface of a first semiconductor layer consisting of either an n-type nitride-based semiconductor layer or a nitride-based semiconductor substrate having a wurtzite structure and thereafter forming an n-side electrode on the etched back surface of the first semiconductor layer.

Abstract: A sub-substrate, a blue-violet semiconductor laser device, an insulating layer, and a red semiconductor laser device are stacked in order on a support member through a plurality of fusion layers. The insulating layer is stacked on an n-side pad electrode of the blue-violet semiconductor laser device, and a conductive layer is formed on the insulating layer. The red semiconductor laser device is stacked on the conductive layer through a fusion layer. The conductive layer is electrically connected to a p-side pad electrode of the red semiconductor laser device. The n-side pad electrode of the blue-violet semiconductor laser device and the n-side pad electrode of the red semiconductor laser device are electrically connected to each other.

Abstract: A method of fabricating a nitride-based semiconductor device capable of reducing contact resistance between a nitrogen face of a nitride-based semiconductor substrate or the like and an electrode is provided. This method of fabricating a nitride-based semiconductor device comprises steps of etching the back surface of a first semiconductor layer consisting of either an n-type nitride-based semiconductor layer or a nitride-based semiconductor substrate having a wurtzite structure and thereafter forming an n-side electrode on the etched back surface of the first semiconductor layer.

Abstract: A nitride-based semiconductor device includes a substrate, a first step portion formed on a main surface side of a first side end surface of the substrate, a second step portion formed on the main surface side of a second side end surface substantially parallel to the first side end surface on an opposite side of the first side end surface and a nitride-based semiconductor layer whose first side surface is a (000-1) plane starting from a first side wall of the first step portion and a second side surface starting from a second side wall of the second step portion on the main surface.

Abstract: A semiconductor laser device capable of suppressing damage of a waveguide is obtained. This GaN-based semiconductor laser chip (semiconductor laser device) includes an n-type GaN substrate of a nitride-based semiconductor and a semiconductor layer of a nitride-based semiconductor formed on the n-type GaN substrate and provided with a ridge portion constituting a waveguide extending in a direction F. The ridge portion (waveguide) is formed on a region approaching a first side from the center of the semiconductor layer. On a region opposite to the first side of the ridge portion (waveguide), a cleavage introduction step is formed from the side of the semiconductor layer, to extend in a direction intersecting with the extensional direction F of the ridge portion (waveguide).

Abstract: A semiconductor laser device capable of reducing the threshold current and improving luminous efficiency and a method of fabricating the same are obtained. This semiconductor laser device comprises a semiconductor substrate having a principal surface and a semiconductor element layer, formed on the principal surface of the semiconductor substrate, having a principal surface substantially inclined with respect to the principal surface of the semiconductor substrate and including an emission layer.

Abstract: A nitride-based light-emitting device capable of suppressing reduction of the light output characteristic as well as reduction of the manufacturing yield is provided. This nitride-based light-emitting device comprises a conductive substrate at least containing a single type of metal and a single type of inorganic material having a lower linear expansion coefficient than the metal and a nitride-based semiconductor element layer bonded to the conductive substrate.