According to the present disclosure, techniques related to manufacturing and applications of power photodiode structures and devices based on group-III metal nitride and gallium-based substrates are provided. More specifically, embodiments of the disclosure include techniques for fabricating photodiode devices comprising one or more of GaN, AlN, InN, InGaN, AlGaN, and AlInGaN, structures and devices. Such structures or devices can be used for a variety of applications including optoelectronic devices, photodiodes, power-over-fiber receivers, and others.

A light emitting device with on-chip optical power readout includes a light emitting mesa and a light detecting mesa formed adjacent to each other on the same substrate of a chip, and a portion of the light emitted from the light emitting mesa is transmitted to the light detecting mesa at least through the substrate. The light emitting mesa and the light detecting mesa have exactly the same epitaxial structure and can be electrically isolated from each other by an insulation layer, or an airgap formed therebetween, or by ion implantation. The light emitting mesa and the light detecting mesa can also share an n-type structure and a common n-electrode while having their own p-electrode, respectively.

An integrated circuit structure comprising a substrate having an upper surface; a gallium nitride layer disposed on the upper surface of the substrate; and a photoconductive semiconductor switch laterally disposed alongside a transistor on the gallium nitride layer integrated into the integrated circuit structure wherein a regrown gallium nitride material is disposed on the photoconductive semiconductor switch and operatively coupled with the wafer.

An integrated circuit structure comprising a substrate having an upper surface; a gallium nitride layer disposed on the upper surface of the substrate; and a photoconductive semiconductor switch laterally disposed alongside a transistor on the gallium nitride layer integrated into the integrated circuit structure.

A first data communication device includes a first semiconductor laser for oscillating with electric power, and outputting feed light to a powered device of a second data communication device; a second semiconductor laser for first signals; a first modulator for modulating first laser light output by the second semiconductor laser to first signal light and outputting the first signal light to the second data communication device; and an optical receiver. The second data communication device includes the powered device having a photoelectric conversion element for converting the feed light into the electric power, a third semiconductor laser for second signals, and a second modulator for modulating second laser light output by the third semiconductor laser to second signal light and outputting the second signal light to the first data communication device. The optical receiver receives and converts the second signal light into an electrical signal corresponding to transmission data.

An optical power supply system includes a first data communication device and a second data communication device. The first data communication device includes a power sourcing equipment device including a first semiconductor laser; and a first transmitter including a second semiconductor laser and a first modulator. The second data communication device includes a powered device comprising a photoelectric conversion element; a receiver; a data processing unit; and a second transmitter including a third semiconductor laser and a second modulator. The first data communication device and the second data communication device perform optical communication with each other. The electric power obtained by the conversion of the feed light by the photoelectric conversion element is driving power for the second transmitter and the receiver.

An ultraviolet ray detecting device is provided. The ultraviolet ray detecting device comprises: a substrate; a buffer layer disposed on the substrate; a light absorption layer disposed on the buffer layer; a capping layer disposed on the light absorption layer; and a Schottky layer disposed on a partial region of the capping layer, wherein the capping layer has an energy bandgap larger than that of the light absorption layer.

There is a method for forming a semiconductor nanostructure on a substrate. The method includes placing a substrate and a semiconductor material in a pulsed laser deposition chamber; selecting parameters including a fluence of a laser beam, a pressure P inside the chamber, a temperature T of the substrate, a distance d between the semiconductor material and the substrate, and a gas molecule diameter a.sub.0 of a gas to be placed inside the chamber so that conditions for a Stranski-Krastanov nucleation are created; and applying the laser beam with the selected fluence to the semiconductor material to form a plume of the semiconductor material. The selected parameters determine the formation, from the plume, of (1) a nanolayer that covers the substrate, (2) a polycrystalline wetting layer over the nanolayer, and (3) a single-crystal nanofeature over the polycrystalline wetting layer, and the single-crystal nanofeature is grown free of any catalyst or seeding layer.

A power sourcing equipment (PSE) device of an optical power supply system includes a semiconductor laser that oscillates with electric power, thereby outputting feed light. The semiconductor laser includes a semiconductor region exhibiting a light-electricity conversion effect. A semiconductor material of the semiconductor region is a laser medium having a laser wavelength of 500 nm or less. A powered device of the optical power supply system includes a photoelectric conversion element that converts feed light into electric power. The photoelectric conversion element includes a semiconductor region exhibiting a light-electricity conversion effect. A semiconductor material of the semiconductor region is a laser medium having a laser wavelength of 500 nm or less.

An inexpensive IR photodetector assembly that can provide high performance in SWIR applications, such as LIDAR. The photodetector assembly can operate as a photodiode, a phototransistor, or can include both a photodiode and a phototransistor. The hybrid photodetector can be composed of one or more absorber layer materials from a first semiconductor family, e.g., p-type InGaAs, laying on one or more wide-band gap semiconductor transducer layer materials from a second semiconductor family, e.g., aluminum gallium nitride (AlGaN) and gallium nitride (GaN), or AlGaN/n-GaN. As such, the absorber layer material and the wide band gap materials can be from two different semiconductor families, making the IR photodetector a hybrid of semiconductor families. After shining IR light onto the absorber layer material, the photo-generated electron-hole pairs can be collected as photocurrent in the photo-voltaic mode.