A voltage-matched solar module for converting incident solar radiation into electricity consisting of a plurality of wafer-sized multi-junction solar devices and wiring circuitry adjacent to a module-sized bottom substrate. Each solar device has at least two photovoltaic (PV) cells separated by electrically insulating transparent layers. The PV cells are aligned so as to overlap and are electrically connected to the wiring circuitry by conducting vias. The wiring circuitry includes a multiplicity of serial strings electrically connected in parallel and having substantially the same voltage. A method of producing the solar module is disclosed which utilizes an ALD/LPCVD tool for van der Waals epitaxy of 2D materials.

A voltage-matched solar module for converting incident solar radiation into electricity consisting of a plurality of wafer-sized multi-junction solar devices and wiring circuitry adjacent to a module-sized bottom substrate. Each solar device has at least two photovoltaic (PV) cells separated by electrically insulating transparent layers. The PV cells are aligned so as to overlap and are electrically connected to the wiring circuitry by conducting vias. The wiring circuitry includes a multiplicity of serial strings electrically connected in parallel and having substantially the same voltage. A method of producing the solar module is disclosed which utilizes an ALD/LPCVD tool for van der Waals epitaxy of 2D materials.

The present invention aims to provide a method for producing a solar cell in which a continuous long scribed line is provided along the machine direction of a substrate so that failures due to breakage of the scribed line are reduced. Provided is a method for producing a solar cell, the method being for producing plural monolithic solar cells in batches by a roll-to-roll method, the method including: step (1) of forming a lower electrode on a long substrate and scribing the lower electrode to provide a scribed line along the machine direction of the substrate; step (2) of forming a photoelectric conversion layer on the lower electrode provided with the scribed line and scribing the photoelectric conversion layer to provide a scribed line along the machine direction of the substrate; step (3) of forming an upper electrode on the photoelectric conversion layer provided with the scribed line and scribing the upper electrode to provide a scribed line along the machine direction of the substrate, the scribing in at least one of the steps (1) to (3) including: step (a) of providing a first scribed line; step (b) of providing a second scribed line; and step (c) of providing a third scribed line.

A solar cell device with improved performance and a method of fabricating the same is described. The solar cell includes a back contact layer formed on a substrate, an absorber layer formed on the back contact layer, a buffer layer formed on the absorber layer, and a front contact layer formed by depositing a transparent conductive oxide layer on the buffer layer and annealing the deposited TCO layer.

A solar cell device with improved performance and a method of fabricating the same is described. The solar cell includes a back contact layer formed on a substrate, an absorber layer formed on the back contact layer, a buffer layer formed on the absorber layer, and a front contact layer formed by depositing a transparent conductive oxide layer on the buffer layer and annealing the deposited TCO layer.

A method of forming a photovoltaic product with a plurality of photovoltaic cells is disclosed. The method comprises depositing a stack with first and second electrode layers (12, 16) and a photovoltaic layer (14) arranged in between. The method comprises partitioning the stack. The partitioning includes forming a trench (20) extending through the second electrode layer and the photovoltaic layer to expose the first electrode layer. The stack is first irradiated with a laser beam with a first spotsize and with a first wavelength for which the photovoltaic layer has a relatively high absorption coefficient as compared to that of the second electrode layer. The stack is then irradiated with a second laser beam with a second spotsize, greater than the first spotsize, and with a second wavelength for which the photovoltaic layer has a relatively low absorption coefficient as compared to that of the second electrode layer.

A method of forming a photovoltaic product with a plurality of photovoltaic cells is disclosed. The method comprises depositing a stack with first and second electrode layers (12, 16) and a photovoltaic layer (14) arranged in between. The method comprises partitioning the stack. The partitioning includes forming a trench (20) extending through the second electrode layer and the photovoltaic layer to expose the first electrode layer. The stack is first irradiated with a laser beam with a first spotsize and with a first wavelength for which the photovoltaic layer has a relatively high absorption coefficient as compared to that of the second electrode layer. The stack is then irradiated with a second laser beam with a second spotsize, greater than the first spotsize, and with a second wavelength for which the photovoltaic layer has a relatively low absorption coefficient as compared to that of the second electrode layer.

A photovoltaic device is provided that comprises a photovoltaic active zone being formed of a stack of thin films comprising a first electrode, an absorber film and a metallic electrode. A collection gate is arranged in contact with the first electrode to reduce its electrical resistance and avoid direct physical or electrical contact with the metallic electrode. The photovoltaic active zone includes a plurality of channels, made in the metallic electrode and the absorber film. The collection gate is separated from the metallic electrode and from the absorber film by a dielectric material.

A photovoltaic device is provided that comprises a photovoltaic active zone being formed of a stack of thin films comprising a first electrode, an absorber film and a metallic electrode. A collection gate is arranged in contact with the first electrode to reduce its electrical resistance and avoid direct physical or electrical contact with the metallic electrode. The photovoltaic active zone includes a plurality of channels, made in the metallic electrode and the absorber film. The collection gate is separated from the metallic electrode and from the absorber film by a dielectric material.

A solar cell assembly includes a plurality of solar cells and an inter-cell region provided between adjacent ones of the solar cells included in the plurality of solar cells. Each of the solar cells and the inter-cell region includes: a semiconductor substrate having a first conductivity type and having a first main surface and a second main surface that face away from each other; a first amorphous semiconductor layer having a second conductivity type and being provided on a first main surface side of the semiconductor substrate; an insulating layer provided on part of the first amorphous semiconductor layer; and a first transparent conductive film provided on the first amorphous semiconductor layer so as to cover the insulating layer. In a plan view of the solar cell assembly, the insulating layer is provided along the inter-cell region and partially overlapping the inter-cell region.