A process is provided for contacting a nanostructured surface. In that process, a substrate is provided having a nanostructured material on a surface, the substrate being conductive and the nanostructured material being coated with an insulating material. A portion of the nanostructured material is at least partially removed. A conductor is deposited on the substrate in such a way that it is in electrical contact with the substrate through the area where the nanostructured material has been at least partially removed.

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.

Quantum dots (nanoparticle material) each having a core-shell structure including a core part and a shell part that protects the core part. The shell part of the quantum dot has a thickness T of 3 to 5 ML based on the constituent molecule of the shell part. A light-emitting device includes the quantum dots.

A method of detecting a change in current is provided which includes irradiating light on at least one photoelectric conversion material layer, and detecting an increased change in current generated in the photoelectric conversion material layer. A photoelectric conversion apparatus is also provided and includes a photoelectric conversion element including a photoelectric conversion material layer, and a current detection circuit electrically connected to the photoelectric conversion element. In the photoelectric conversion apparatus, the current detection circuit detects an increased change in current generated in the photoelectric conversion material layer.

Solar cells that include quantum dots are provided. In particular, a solar panel is provided, the solar panel comprising: a first solar cell comprising: a first set of quantum dots in a first semiconductor, the first semiconductor configured to receive one or more of ambient light and sunlight and emit first wavelengths a first range of about 450 nm to about 480 nm, the first set of quantum dots configured to convert the first wavelengths to a first electric output; and, a second solar cell comprising: a second set of quantum dots in a second semiconductor, the second semiconductor configured to receive one or more of the ambient light and the sunlight and emit second wavelengths a second range of about 600 nm to about 700 nm, the second set of quantum dots configured to convert the second wavelengths to a second electric output.

In one aspect, optoelectronic devices are described herein. In some implementations, an optoelectronic device comprises a photovoltaic cell. The photovoltaic cell comprises a space-charge region, a quasi-neutral region, and a low bandgap absorber region (LBAR) layer or an improved transport (IT) layer at least partially positioned in the quasi-neutral region of the cell.

Provided are a method of manufacturing a quantum-dot photoactive-layer including: alternately depositing an amorphous silicon compound layer and a silicon-rich compound layer containing conductive impurities and an excess of silicon based on a stoichiometric ratio on a silicon substrate to form a composite multi-layer; and heat treating the composite multi-layer to form a plurality of silicon quantum-dots in a matrix corresponding to a silicon compound, wherein an amorphous silicon layer containing the conductive impurities is formed at least one time instead of the silicon-rich compound layer, and a quantum-dot photoactive-layer manufactured using the method as described above.

A liquid crystal display device containing a liquid crystal panel that includes a first substrate, a second substrate, and first and second polarizers at respective outer surfaces of the first and second substrates; and a backlight unit under the liquid crystal panel that includes a light source, wherein the light source includes a first luminous body having a first peak wavelength, a second luminous body having a second peak wavelength greater than the first peak wavelength, and a third luminous body having a third peak wavelength greater than the second peak wavelength, and wherein the first polarizer contains a light absorption layer having an absorption peak between the second peak wavelength and the third peak wavelength.

Conductive features of a device including quantum dots of a first substrate are bonded to conductive features of a second substrate. A quantum dot layer is formed on the first substrate having conductive features in a dielectric layer. Hybrid bonding of the first substrate to the second substrate is performed without use of an intervening adhesive to connect the first conductive features and the second conductive features.

An image sensor using quantum dots is formed that improves collection of photogenerated carrier using a conductive matrix, a semiconductive matrix, a matrix comprising conductive particles and quantum dots in a transparent non-conductive material, conductive structures, and/or porous conductive structures. Hybrid bonding of the image sensor to an image processor device is performed without use of an intervening adhesive to connect the image sensor to the image processor device.