A method for edge passivation of crystalline silicon-based shingle cells, in which multiple crystalline silicon-based shingle cells are stacked to form a shingle cell group with cut edges thereof co-planar to form a to-be-passivated surface, and then the shingle cell group is placed in a fixing tooling to form a passivation unit. The passivation unit is conveyed by a conveying mechanism to an evaporation and annealing mechanism. A first source material is evaporated at 20-300 C. under vacuum in the evaporation and annealing mechanism to form a first gaseous source material, which is deposited on the to-be-passivated surface to form a first passivation layer. The shingle cell group with the first passivation layer is annealed at 100-350 C. A passivation device for implementing such method is further provided.

The present invention discloses a manufacturing method of a solar cell, including: forming an electricity generation layer on a substrate; forming an ohmic contact layer on a surface of the electricity generation layer facing away from the substrate; forming a back electrode on a surface of the substrate facing away from the electricity generation layer; and forming a top electrode on a surface of the ohmic contact layer facing away from the electricity generation layer using a printing process. The present invention discloses a solar cell. The present invention solves the problem of low capacity of the solar cell at present.

A solar cell includes a light-receiving surface electrode formed on a light-receiving surface, a back surface electrode formed on a backside, and a CZ silicon single crystal substrate doped with gallium. The CZ silicon single crystal substrate contains 12 ppm or more oxygen atoms. A spiral oxygen-induced defect is not observed in an EL (electroluminescence) image of the solar cell.

Provided are photovoltaic devices with polycrystalline type II-VI semiconductor absorber materials including n-type absorber compositions and having p-type hole contact layers are described herein. Methods of treating semiconductor absorber layers and forming hole contact layers are described.

A method of fabricating a solar cell is disclosed. The method can include forming a dielectric region on a surface of a solar cell structure and forming a metal layer on the dielectric layer. The method can also include configuring a laser beam with a particular shape and directing the laser beam with the particular shape on the metal layer, where the particular shape allows a contact to be formed between the metal layer and the solar cell structure.

Provided is a solar cell and a photovoltaic module. The solar cell includes a silicon substrate, and the silicon substrate includes a front surface and a back surface arranged opposite to each other. P-type conductive regions and N-type conductive regions are alternately arranged on the back surface of the silicon substrate. Front surface field regions are located on the front surface of the silicon substrate and spaced from each other. The front surface field regions each corresponds to one of the P-type conductive regions or one of the N-type conductive regions. At least one front passivation layer is located on the front surface of the silicon substrate. At least one back passivation layer is located on surfaces of the P-type conductive regions and N-type conductive regions.

A solar cell and a preparation method thereof are provided. A method for preparing the solar cell includes following steps: forming an amorphous silicon layer on a tunneling oxide layer at a first side; forming a doped polycrystalline silicon layer in a first process by a diffusion doping treatment; forming a doped oxide layer on the doped polycrystalline silicon layer in a second process; and after the doped oxide layer is formed, doping the first side selectively and heavily by a laser doping process, and forming a selective emitter region in a heavily doped region.

A photovoltaic device and a method of making a photovoltaic device that includes a stack of layers, including a substrate and an electrode layer. The photovoltaic device includes a semiconductor light absorption layer that is formed on the stack by a coating liquid that includes a plurality of semiconducting particles. The coating liquid may also include a solvent and a plurality of additive molecules. The photovoltaic device also includes a transparent conducting layer disposed on the semiconductor light absorption layer and a grid electrode disposed on the transparent conducting layer.

Solar cells of varying composition are disclosed, generally including a central substrate, conductive layer(s), antireflection layers(s), passivation layer(s) and/or electrode(s). Multifunctional layers provide combined functions of passivation, transparency, sufficient conductivity for vertical carrier flow, the junction, and/or varying degrees of anti-reflectivity. Improved manufacturing methods including single-side CVD deposition processes and thermal treatment for layer formation and/or conversion are also disclosed.

Photovoltaic cells having copper contacts can be made by using copper nanoparticles during their fabrication. Such photovoltaic cells can include a copper-based current collector located on a semiconductor substrate having an n-doped region and a p-doped region. The semiconductor substrate is configured for receipt of electromagnetic radiation and generation of an electrical current therefrom. The copper-based current collector includes an electrically conductive diffusion barrier disposed on the semiconductor substrate and a copper contact disposed on the electrically conductive diffusion barrier. The copper contact is formed from copper nanoparticles that have been at least partially fused together. The electrically conductive diffusion barrier limits the passage of copper therethrough.