A substrate carrier, includes: a unitary body fabricated from a single block of graphite, wherein the body comprises a back plate, and a pair of spaced apart, substantially parallel, side rails, wherein each of the side rails comprises: an inwardly facing surface extending outwardly of the back plate; a longitudinally extending selenium vapor bore formed therein, a top end of the selenium vapor bore being open and configured for coupling to a selenium supply container for receiving selenium vapor by gravity, a bottom end of the selenium vapor bore being closed; an inwardly directed selenium vapor channel; a plurality of selenium vapor outlets disposed between the selenium vapor bore and the inwardly directed selenium vapor channel so as provide a plurality of conduits between the selenium vapor bore and the selenium vapor channel; and, a longitudinally extending engagement slot formed in the inwardly facing surface of each side rail adjacent the back plate to engage and hold a substrate in proximity to the back plate.

Embodiments of the present disclosure relate to photovoltaic devices, CIGS containing films, and methods of manufacturing CIGS containing films and photovoltaic devices to improve quantum efficiency, reduce interface charges, electron losses, and electron re-combinations. The CIGS layers in the photovoltaic devices described herein may be deposited using physical vapor deposition, followed by in-situ oxygen annealing, and further followed by deposition of a cap layer over the CIGS layer without subjecting the CIGS layer to an air break.

A method for forming a photovoltaic device comprising the steps of: providing a first conductive material on a substrate; depositing a continuous layer of a dielectric material less than 10 nm thick on the first conductive material; annealing the first conductive material and the layer of dielectric material; forming a chalcogenide light-absorbing material on the layer of dielectric material; and depositing a second material on the light-absorbing material such that the second material is electrically coupled to the light-absorbing material; wherein the first conductive material and the dielectric material are selected such that, during the step of annealing, a portion of the first conductive material undergoes a chemical reaction to form: a layer of a metal chalcogenide material at the interface between first conductive material and the dielectric material; and a plurality of openings in the layer of dielectric material; the openings being such to allow electrical coupling between the light-absorbing material and the layer of a metal chalcogenide material. Additionally contemplated is a photovoltaic device formed by this method.

The embodiment of the application discloses a photoelectric sensor and a manufacturing method thereof, wherein the photoelectric sensor comprises: a light absorbing layer for absorbing incident light to generate a photocurrent, the light absorption layer comprises a first absorption layer and a second absorption layer stacked in the direction of incident light, the first absorption layer being an intrinsic semiconductor layer of the photoelectric sensor, the second absorption layer being made of a material having a higher photoelectric conversion efficiency than the first absorption layer, and the second absorption layer has a stripe structure arranged at intervals.

Provided is a multi-junction solar cell in which two or more absorption layers having different bandgaps are stacked on one another. The multi-junction solar cell includes a first cell including a first absorption layer, and a second cell electrically connected in series onto the first cell, wherein the second cell includes a second absorption layer having a higher bandgap compared to the first absorption layer, and a plurality of recesses penetrating through the second absorption layer.

Tandem solar cell configurations are provided where at least one of the cells is a metal chalcogenide cell. A four-terminal tandem solar cell configuration has two electrically independent solar cells stacked on each other. A two-terminal solar cell configuration has two electrically coupled solar cells (same current through both cells) stacked on each other. Carrier selective contacts can be used to make contact to the metal chalcogenide cell (s) to alleviate the troublesome Fermi level pinning issue. Carrier-selective contacts can also remove the need to provide doping of the metal chalcogenide. Doping of the metal chalcogenide can be provided by charge transfer. These two ideas can be practiced independently or together in any combination.

Methods of making a semiconductor layer from nanocrystals are disclosed. A film of nanocrystals capped with a ligand can be deposited onto a substrate; and the nanocrystals can be irradiated with one or more pulses of light. The pulsed light can be used to substantially remove the ligands from the nanocrystals and leave the nanocrystals unsintered or sintered, thereby providing a semiconductor layer. Layered structures comprising these semiconductor layers with an electrode are also disclosed. Devices comprising such layered structures are also disclosed.

A sputter deposition method includes sputtering a first target material onto a web substrate moving through a first process module while heating the substrate, providing the substrate from the first process module to a connection unit containing a roller assembly including a plurality of cylindrical rollers, bending the substrate at an angle of 10° to 40° around the roller assembly in the connection unit, providing the substrate from the connection unit to a second process module, and sputtering a second target material onto the substrate moving through the second process module while heating the substrate.

A solar cell of an embodiment includes: a first electrode; a second electrode; a light-absorbing layer interposed between the first electrode and the second electrode; a dot region interposed between the first electrode and the light-absorbing layer, the dot region including dots.

Present subject matter provides a semiconductor nanocrystal comprises a core and a shell. The core is fabricated from a first semiconductor. The shell is fabricated from a second semiconductor. The optical cross section of the semiconductor nanocrystal is in a range of 10.sup.−17 cm.sup.2-10.sup.−12 cm.sup.2 in a 2-3 eV region. The core is less than 2 nanometers from an outer surface of the shell in at least one region of the semiconductor nanocrystal. Present subject matter also provides method for preparation of the semiconductor nanocrystals and method for photosynthesis of organic compounds.