A chip package includes a semiconductor substrate, an anti-reflection layer, and a metal multi-layer. The semiconductor substrate has an optical sensing area. The anti-reflection layer is located on the semiconductor substrate. The metal multi-layer is located on and in contact with the anti-reflection layer. The metal multi-layer includes a redistribution line and two probe pads. Two ends of the redistribution line respectively extend to the two probe pads. The redistribution line is located in the optical sensing area, and the two probe pads are located outside the optical sensing area. The orthographic projection area of the redistribution line in the optical sensing area is less than 1% of the area of the optical sensing area.

A display module and system applications including a display module are described. The display module may include a display substrate including a front surface, a back surface, and a display area on the front surface. A plurality of interconnects extend through the display substrate from the front surface to the back surface. An array of light emitting diodes (LEDs) are in the display area and electrically connected with the plurality of interconnects, and one or more driver circuits are on the back surface of the display substrate. Exemplary system applications include wearable, rollable, and foldable displays.

A composite material for fluorescent quantum dot micro-nano packaging. The composite material comprises fluorescent quantum dots, a mesoporous particle material having a nanometer lattice structure, and a barrier layer, wherein the fluorescent quantum dots are distributed in the mesoporous particle material, and the barrier layer is coated on the outer surface of the mesoporous particle material. In the composite material according to the invention, the quantum dot aggregation can be effectively retarded, with the barrier layer coated on the surface the water-oxygen micromolecule erosion is prevented, the compatibility and stability of the composite fluorescent particles is improved, and the service life of the composite material for fluorescent quantum dot micro-nano packaging is thus greatly improved.

A solar cell according to an embodiment of the present disclosure includes a first passivation layer including a first aluminum oxide layer positioned on a first conductivity-type region composed of a polycrystalline silicon layer having an n-type conductivity and having hydrogen, and a first dielectric layer positioned on the first aluminum oxide layer and including a material different from the first aluminum oxide layer.

The present disclosure relates to a heterojunction solar cell, a manufacturing method thereof and a photovoltaic module. The heterojunction solar cell includes a substrate of a first conductivity type, a tunnel layer located on a light-receiving surface of the substrate, and a doped polysilicon layer located on a top surface of the tunnel layer. The doped polysilicon layer has the first conductivity type.

A solid-state imaging device includes: a pixel region in which a plurality of pixels composed of a photoelectric conversion section and a pixel transistor is arranged; an on-chip color filter; an on-chip microlens; and a multilayer interconnection layer in which a plurality of layers of interconnections is formed through an interlayer insulating film. The solid-state imaging device further includes a light-shielding film formed through an insulating layer in a pixel boundary of a light receiving surface in which the photoelectric conversion section is arranged.

Semiconductor materials offer several potential benefits as active elements in the development of harvesting-energy conversion technologies. In particular, lead selenide (PbSe) semiconductors have been used and proposed to design solar energy harvesting devices, IR sensors, FET devices, amongst others. The present disclosure provides a lead selenide capped with an aromatic ligand. The use of an aromatic ligand, and more specifically benzoic acid, provides robustness and more durability to the lead selenide, and therefore prevents the lead selenide from breaking or cracking easily. Also the aromatic ligand prevents the degradation and oxidation of the lead selenide, without affecting any of the lead selenide electronic and chemical characteristics.

A solar cell, a manufacturing method thereof, and a photovoltaic module are provided. The solar cell includes a substrate having electrode regions and non-electrode regions that are alternatingly arranged in a first direction, where the non-electrode regions of the substrate include a plurality of first regions and a plurality of second regions; a doped conductive layer formed over the dielectric layer; a passivation layer formed over the first regions and the doped conductive layer; and a plurality of electrodes.

A photo detecting device comprising: a substrate; a plurality of photoelectric conversion elements provided to the substrate and configured to output a detection signal corresponding to light with which the photoelectric conversion elements are irradiated; at least one or more light emitting elements provided to the substrate; and a control circuit configured to set a wavelength of light output from the light emitting element by controlling an electric current flowing through the light emitting element.

Described herein are photovoltaic devices and methods which utilize femtosecond (fs) lasers to create a glass/glass weld, hermetically encapsulating photovoltaic devices that provide both reduced cost and increased cell life and efficiency. For example, glass/glass welds can reduce manufacturing time and costs, increase cell life by removing encapsulant failure which is a leading cause of cell degradation and provide for increased optical properties, which improves cell efficiency.