A cap is mounted to a support substrate, the cap including a cap body and an optical shutter. The cap and support substrate define a housing. An electronic chip is disposed in the housing above the support substrate. A face of the electronic chip supports an optical device that is optically coupled with the optical shutter. The cap body is thermally conductive. Within the housing, a thermally conductive linking structure is coupled in a thermally conductive manner between the cap body and the electronic chip. The thermally conductive linking structure surrounds the electronic chip. A thermal interface material fills a portion of the housing between the thermally conductive linking structure and the cap body.

The photodetector includes a light receiving element and a package. The package has an accommodation member formed of a ceramic, a wiring including a pad connected to a terminal of the light receiving element by a wire, and a light transmitting member. A bottom wall of the accommodation member has a placement surface to which the light receiving element is attached by an adhesive member. The bottom wall or a side wall of the accommodation member has a pad surface on which the pad is disposed, the pad surface positioned on an opening side of the accommodation member with respect to the placement surface. The side wall has a through hole. At least a portion of an inner end portion of the through hole is positioned on the opening side with respect to a surface of the light receiving element on the opening side.

In one example, a semiconductor device comprises a spacer substrate, a first lens substrate over the first spacer substrate, and a lens protector over the first lens dielectric adjacent to the first lens. The spacer substrate comprises a spacer dielectric, a spacer top terminal, a spacer bottom terminal, and a spacer via. The first lens substrate comprises a first lens dielectric, a first lens, a first lens top terminal, a first lens bottom terminal, and a first lens via. A first interconnect is coupled with the spacer top terminal and the first lens bottom terminal. Other examples and related methods are also disclosed herein.

Disclosed is a method for fabricating a terahertz device, the method including providing a substrate, doping a conductive impurity on an upper surface of the substrate to form an electrode layer, patterning the electrode layer to form antenna electrodes, and forming a photomixer between the antenna electrodes.

A solar cell module comprising a plurality of solar cells mounted on a flexible support, the support comprising a conductive layer on the top surface thereof divided into two electrically isolated portions—a first conductive portion and a second conductive portion. Each solar cell comprises a front surface, a rear surface, and a first contact on the rear surface and a second contact on the front surface. Each one of the plurality of solar cells is placed on the first conductive portion with the first contact electrically connected to the first conductive portion so that the solar cells are connected through the first conductive portion. A second contact of each solar cell is then connected to the second conductive portion by a respective interconnect.

An embodiment device includes: a first dielectric layer; a first photonic die and a second photonic die disposed adjacent a first side of the first dielectric layer; a waveguide optically coupling the first photonic die to the second photonic die, the waveguide being disposed between the first dielectric layer and the first photonic die, and between the first dielectric layer and the second photonic die; a first integrated circuit die and a second integrated circuit die disposed adjacent the first side of the first dielectric layer; conductive features extending through the first dielectric layer and along a second side of the first dielectric layer, the conductive features electrically coupling the first photonic die to the first integrated circuit die, the conductive features electrically coupling the second photonic die to the second integrated circuit die; and a second dielectric layer disposed adjacent the second side of the first dielectric layer.

A package structure is provided. The package structure includes a substrate, a sensor device, an encapsulant and a signal blocking structure. The substrate has a signal passing area. The sensor device is disposed over the substrate. The sensor device has a first surface, a second surface opposite to the first surface and a sensing area located at the second surface. The second surface of the sensor device faces the substrate. The encapsulant covers the sensor device and the substrate. The signal blocking structure extends from the substrate into the encapsulant.

A method for adjusting an optical system is provided, including a positioning device positioning a first optical module; a measuring device measuring an angular difference between a main axis of the first optical module and an optical axis of an optical element sustained by the first optical module to obtain a measurement information; an adjusting device changing the shape of an adjustment assembly of the first optical module according to the measurement information; and assembling the first optical module with an optical object, wherein the optical axis of the optical element is parallel to a central axis of the optical object.

A cover for an electronic package is manufactured by placing an optical insert, having opposite faces and configured to allow light radiation to pass therethrough, between two opposite faces of a cavity of a mold in a position such that said optical faces of the optical insert make contact with said opposite faces of the cavity of the mold. A coating material is injected into the cavity and around the optical insert. The coating material is set to obtain a substrate that is overmolded around the optical insert so as to produce the cover. An electronic package includes an electronic chip mounted to a support substrate with the cover formed by the overmolded substrate mounted to the support substrate.

Disclosed are structures and methods related to metallization of a doped gallium arsenide (GaAs) layer. In some embodiments, such metallization can include a tantalum nitride (TaN) layer formed on the doped GaAs layer, and a metal layer formed on the TaN layer. Such a combination can yield a Schottky diode having a low turn-on voltage, with the metal layer acting as an anode and an electrical contact connected to the doped GaAs layer acting as a cathode. Such a Schottky diode can be utilized in applications such as radio-frequency (RF) power detection, reference-voltage generation using a clamp diode, and photoelectric conversion. In some embodiments, the low turn-on Schottky diode can be fabricated utilizing heterojunction bipolar transistor (HBT) processes.