An optical device includes: a substrate having a first surface, and a second surface opposite of the first surface; a plurality of surface emitting laser elements provided on the first surface of the substrate and configured to emit light in a direction intersecting the first surface; a plurality of optical elements disposed on the second surface so as to respectively correspond to the plurality of surface emitting laser elements; and an anti-reflection structure between the substrate and the plurality of optical elements.

A semiconductor light-emitting device, includes: a semiconductor light-emitting element; a support including a base and a conductive part and configured to support the semiconductor light-emitting element; and a cover configured to overlap the semiconductor light-emitting element as viewed in a first direction, and to transmit light from the semiconductor light-emitting element, wherein the cover includes a base layer having a front surface and a rear surface which transmit the light from the semiconductor light-emitting element and face opposite sides to each other in the first direction, wherein the rear surface faces the semiconductor light-emitting element, wherein the base layer includes a plurality of undulation parts bonded to the support by a bonding material, and wherein the undulation parts are more uneven than the rear surface.

An optical semiconductor device includes an optical semiconductor chip in which at least one optical element is formed in a semiconductor substrate, and an extended wire pattern that is connected to a first electrode and a second electrode of the optical element and that extends outside the optical semiconductor chip. The first electrode and the second electrode of the optical semiconductor device are formed on the front surface side of the optical semiconductor chip, and the extended wire pattern is disposed on the front surface of the optical semiconductor chip or disposed at a position apart from the front surface.

An optical semiconductor device includes an optical semiconductor chip in which at least one optical element is formed in a semiconductor substrate, and an extended wire pattern that is connected to a first electrode and a second electrode of the optical element and that extends outside the optical semiconductor chip. The first electrode and the second electrode of the optical semiconductor device are formed on the front surface side of the optical semiconductor chip, and the extended wire pattern is disposed on the front surface of the optical semiconductor chip or disposed at a position apart from the front surface.

A light-emitting body includes a base semiconductor part including a nitride semiconductor, a compound semiconductor part including a nitride semiconductor and positioned above the base semiconductor part, and a first electrode and a second electrode. The base semiconductor part includes first part and second part having a density of threading dislocation extending in a thickness direction lower than that of the first part, at least part of the first electrode and at least part of the second electrode are positioned on the compound semiconductor part, and at least part of the first electrode is positioned above the second part.

A method of transfer printing. The method comprising: providing a precursor photonic device, comprising a substrate and a bonding region, wherein the precursor photonic device includes one or more alignment marks located in or adjacent to the bonding region; providing a transfer die, said transfer die including one or more alignment marks; aligning the one or more alignment marks of the precursor photonic device with the one or more alignment marks of the transfer die; and bonding at least a part of the transfer die to the bonding region.

Optoelectronic devices and method of forming the same include an optoelectronic component in a substrate layer. An integrated circuit chip is positioned on the substrate layer. A lens is positioned on the substrate layer directly above the optoelectronic component and above at least part of the integrated circuit chip. The lens has a cut-out portion that accommodates the integrated circuit chip.

An external cavity tunable laser includes a gain median module to generate a broadband optical spectrum covering a predetermined wavelength range; a collimate lens turning a diverging beam into a collimated beam; a pair of etalons to tune frequency; an actuator to adjust an external cavity optical pathlength; a bandpass filter to block one or more frequencies outside the predetermined wavelength range; a beam splitter to split a percentage of the beam to a photodetector; a reflection mirror for feedback to gain median waveguide; an isolator for preventing reflecting light back to the external cavity; and a hermetically sealed housing less than 0.15 cubic centimeters.

The invention relates to a laser chip located between a first and a second electrically and thermally conductive component, wherein: a first lateral surface of the laser chip is connected in a planar manner to a first lateral surface of the first component; the second lateral surface of the laser chip is connected in a planar manner to a first lateral surface of the second component; the laser chip has a radiation side which is located between the components; the radiation side is arranged set back inwardly at a predefined distance from the first end faces of the components; and a radiation space, which extends from the radiation side of the laser chip to the first end faces of the components is formed between the first lateral surfaces of the two components and adjacent to the radiation side of the laser chip.

The invention relates to a laser chip located between a first and a second electrically and thermally conductive component, wherein: a first lateral surface of the laser chip is connected in a planar manner to a first lateral surface of the first component; the second lateral surface of the laser chip is connected in a planar manner to a first lateral surface of the second component; the laser chip has a radiation side which is located between the components; the radiation side is arranged set back inwardly at a predefined distance from the first end faces of the components; and a radiation space, which extends from the radiation side of the laser chip to the first end faces of the components is formed between the first lateral surfaces of the two components and adjacent to the radiation side of the laser chip.