The present invention relates to a solid state switch that may be used as in optically-triggered switch in a variety of applications. In particular, the switch may allow for the reduction of gigawatt systems to approximately shoebox-size dimension. The optically-triggered switches may be included in laser triggered systems or antenna systems.

Optoelectronic detectors having one or more dilute nitride layers on substrates with lattice parameters matching or nearly matching GaAs are described herein. A semiconductor can include a substrate with a lattice parameter matching or nearly matching GaAs and a first doped III-V layer over the substrate. The semiconductor can also include an absorber layer over the first doped III-V layer, the absorber layer having a bandgap between approximately 0.7 eV and 0.95 eV and a carrier concentration less than approximately 1×10.sup.16 cm.sup.−3 at room temperature. The semiconductor can also include a second doped III-V layer over the absorber layer.

Semiconductor optoelectronic devices having a dilute nitride active region are disclosed. In particular, the semiconductor devices have a dilute nitride active region with at least two bandgaps within a range from 0.7 eV and 1.4 eV. Photodetectors comprising a dilute nitride active region with at least two bandgaps have a reduced dark current when compared to photodetectors comprising a dilute nitride active region with a single bandgap equivalent to the smallest bandgap of the at least two bandgaps.

Systems and methods for optical data communication in high temperatures and harsh environments are provided herein. The embodiments utilize a combination of a short wavelength light source combined with a wide bandgap detector in order to transmit optical signals. An optical data communication system may include a light source connected to a light detector via an optical fiber. The light source and the light detector may also be physically adjacent to any dielectric gap that can be spanned without having an optical fiber intermediary.

A photo detector includes a superlattice with an undoped first semiconductor layer including undoped intrinsic semiconductor material, a doped second semiconductor layer having a first conductivity type on the first semiconductor layer, an undoped third semiconductor layer including undoped intrinsic semiconductor material on the second semiconductor layer, and a fourth semiconductor layer having a second opposite conductivity type on the third semiconductor layer, along with a first contact having the first conductivity type in the first, second, third, and fourth semiconductor layers, and a second contact having the second conductivity type and spaced apart from the first contact in the first, second, third, and fourth semiconductor layers. An optical shield on a second shielded portion of a top surface of the fourth semiconductor layer establishes electron and hole lakes. A packaging structure includes an opening that allows light to enter an exposed first portion of the top surface of the fourth semiconductor layer.

Semiconductor optoelectronic devices having a dilute nitride active region are disclosed. In particular, the semiconductor devices have a dilute nitride active region with at least two bandgaps within a range from 0.7 eV and 1.4 eV. Photodetectors comprising a dilute nitride active region with at least two bandgaps have a reduced dark current when compared to photodetectors comprising a dilute nitride active region with a single bandgap equivalent to the smallest bandgap of the at least two bandgaps.

Semiconductor structures including optically-transparent metamorphic buffer regions, devices employing such structures, and methods of fabrication. The optically-transparent metamorphic buffer is grown to provide a lattice constant transition between a smaller lattice constant and a larger lattice constant (or vice-versa), allowing materials with two different lattice constants to be monolithically integrated. Such buffer layer may include at least two elements from group V of the periodic table. The optically-transparent metamorphic buffer region may include digital-alloy superlattice structure (s) to confine material defects to the metamorphic buffer layer, and improve electrical properties of the metamorphic buffer layer, thereby improving the electronic properties of electronic devices such as optoelectronic devices and photovoltaic cells. Photonic devices such as solar cells and optical detectors containing such semiconductor structures.

High-voltage solid-state transducer (SST) devices and associated systems and methods are disclosed herein. An SST device in accordance with a particular embodiment of the present technology includes a carrier substrate, a first terminal, a second terminal and a plurality of SST dies connected in series between the first and second terminals. The individual SST dies can include a transducer structure having a p-n junction, a first contact and a second contact. The transducer structure forms a boundary between a first region and a second region with the carrier substrate being in the first region. The first and second terminals can be configured to receive an output voltage and each SST die can have a forward junction voltage less than the output voltage.

Methods and apparatus for processing a photonic device are provided herein. For example, methods include etching, using a plasma etch process that uses a first gas, a first epitaxial layer of material of the photonic device comprising a base layer comprising at least one of silicon, germanium, sapphire, aluminum indium gallium arsenide (Al.sub.xIn.sub.yGa.sub.1-x-yAs), aluminum indium gallium phosphide (Al.sub.xIn.sub.yGa.sub.1-x-yP), aluminum indium gallium nitride (Al.sub.xIn.sub.yGa.sub.1-x-yN), aluminum indium gallium arsenide phosphide (Al.sub.xIn.sub.yGa.sub.1-x-yAs.sub.zP.sub.1-z), depositing, using a plasma deposition process that uses a second gas different from the first gas, a first dielectric layer over etched sidewalls of the first epitaxial layer of material, etching, using the first gas, a second epitaxial layer of material of the photonic device, and depositing, using the second gas, a second dielectric layer over etched sidewalls of the second epitaxial layer of material.

Disclosed herein are photonic materials. The photonic materials can comprise: a first layer comprising In.sub.xGa.sub.1-xN, wherein x is from 0 to 0.5; a second layer comprising ZnSnN.sub.2; and a third layer comprising In.sub.yGa.sub.1-yN, wherein y is from 0 to 0.5; wherein the second layer is disposed between and in contact with the first layer and the third layer, such that the second layer is sandwiched between the first layer and the third layer. In some examples, the photonic materials can be sandwiched between two or more barrier layers to form a quantum well.