A photodiode includes a p-type ohmic contact and a p-type substrate in contact with the p-type ohmic contact. An intrinsic layer is formed over the substrate and including a III-V material. A transparent II-VI n-type layer is formed on the intrinsic layer and functions as an emitter and an n-type ohmic contact.

There is provided an optical sensor package including a semiconductor base layer. A first surface of the semiconductor base layer is formed with a pixel array, a plurality of solder balls and an optical component such that when the optical sensor package is assembled with a substrate, the optical component is accommodated in an accommodation throughhole of the substrate so as to reduce the total thickness.

A solid-state imaging device includes a plurality of photoelectric converting units and a plurality of charge-accumulating units each accumulating a charge generated in the corresponding photoelectric converting unit. The photoelectric converting unit includes a photosensitive region that generates the charge in accordance with light incidence, and an electric potential gradient forming unit that accelerates migration of charge in a second direction in the photosensitive region. The charge-accumulating unit includes: a plurality of regions (semiconductor layers) having an impurity concentration gradually changed in one way in the second direction, and electrodes adapted to apply electric fields to the plurality of regions. Each of the electrodes is disposed over the plurality of regions having the impurity concentration gradually varied.

We disclose an array of Infra-Red (IR) detectors comprising at least one dielectric membrane formed on a semiconductor substrate comprising an etched portion; at least two IR detectors, and at least one patterned layer formed within or on one or both sides of the said dielectric membrane for controlling the IR absorption of at least one of the IR detectors. The patterned layer comprises laterally spaced structures.

An optoelectronic semiconductor component and a method for producing an optoelectronic semiconductor component are disclosed. In an embodiment an optoelectronic semiconductor component includes a semiconductor body with a contact metallization located at a main surface of the semiconductor body, a protective layer partially covering the semiconductor body and the contact metallization, a substrate firmly bonded to the semiconductor body at the main surface, a recess and a terminal layer arranged within the recess, wherein the recess and the terminal layer extend from a side of the substrate facing away from the semiconductor body through the substrate and the protective layer up to the contact metallization, and wherein the terminal layer electrically contacts the contact metallization and a connection layer located between the substrate and the semiconductor body, the connection layer including a first region and a second region, wherein the first region is bonded together with the second region without using a bonding agent.

A packaged device includes an extended structure located at a major side of the packaged device. The extended structure defines an outer area that includes encapsulated material on the major side and an inner area where there is a lack of encapsulant over a portion of the device at the major side. The extended structure prevents encapsulant from getting into the inner area during the encapsulating process.

A method for manufacturing an optical-semiconductor device, including forming a plurality of first and second electrically conductive members that are disposed separately from each other on a support substrate; providing a base member formed from a light blocking resin between the first and second electrically conductive members; mounting an optical-semiconductor element on the first and/or second electrically conductive member; covering the optical-semiconductor element by a sealing member formed from a translucent resin; and obtaining individual optical-semiconductor devices after removing the support substrate.

The present disclosure provides a biological detection device and a processing method of the same. The biological detection device comprises a chip, a light emitter, a circuit board and a covering layer. The chip comprises a photoelectric converter, and the covering layer is covered on the chip, the photoelectric converter and the light emitter; the covering layer is light transmissive; the light emitter emits light; the photoelectric converter receives the light emitted by the light emitter, and is further used for performing photoelectric converting on the light so as to obtain an electrical signal; the chip detects an object to be detected according to the electrical signal; and the circuit board provides a communication channel and power supply for the chip and the light emitter. The technical solution of the present disclosure can improve flexibility of using the biological detection device, and prevent fingerprint recognition from being cracked by prosthesis.

A semiconductor device, which is configured as a backside illuminated solid-state imaging device, includes a stacked semiconductor chip which is formed by bonding two or more semiconductor chip units to each other and in which, at least, a pixel array and a multi-layer wiring layer are formed in a first semiconductor chip unit and a logic circuit and a multi-layer wiring layer are formed in a second semiconductor chip unit; a semiconductor-removed region in which a semiconductor section of a part of the first semiconductor chip unit is completely removed; and a plurality of connection wirings which is formed in the semiconductor-removed region and connects the first and second semiconductor chip units to each other.

One embodiment relates to a method of fabricating a solar cell. A silicon lamina is cleaved from the silicon substrate. The backside of the silicon lamina includes the P-type and N-type doped regions. A metal foil is attached to the backside of the silicon lamina. The metal foil may be used advantageously as a built-in carrier for handling the silicon lamina during processing of a frontside of the silicon lamina. Another embodiment relates to a solar cell that includes a silicon lamina having P-type and N-type doped regions on the backside. A metal foil is adhered to the backside of the lamina, and there are contacts formed between the metal foil and the doped regions. Other embodiments, aspects and features are also disclosed.