The present application provides a silicon-based heterojunction solar cell and a manufacturing method thereof. The silicon-based heterojunction solar cell includes: a silicon substrate, as well as a first passivation layer, an N-type doped layer, a first transparent conductive oxide layer and a first electrode. The first passivation layer, the N-type doped layer, the first transparent conductive oxide layer and the first electrode are sequentially stacked on the front side of the silicon substrate along a first direction. The first passivation layer includes a first sub-passivation layer, a carbon-doped amorphous silicon layer and a second sub-passivation layer which are sequentially stacked along the first direction.

The present application provides a silicon-based heterojunction solar cell and a manufacturing method thereof. The silicon-based heterojunction solar cell includes: a silicon substrate, as well as a first passivation layer, an N-type doped layer, a first transparent conductive oxide layer and a first electrode. The first passivation layer, the N-type doped layer, the first transparent conductive oxide layer and the first electrode are sequentially stacked on the front side of the silicon substrate along a first direction. The first passivation layer includes a first sub-passivation layer, a carbon-doped amorphous silicon layer and a second sub-passivation layer which are sequentially stacked along the first direction.

The present application provides a silicon-based heterojunction solar cell and a manufacturing method thereof. The silicon-based heterojunction solar cell includes: a silicon substrate, as well as a first passivation layer, an N-type doped layer, a first transparent conductive oxide layer and a first electrode. The first passivation layer, the N-type doped layer, the first transparent conductive oxide layer and the first electrode are sequentially stacked on the front side of the silicon substrate along a first direction. The first passivation layer includes a first sub-passivation layer, a carbon-doped amorphous silicon layer and a second sub-passivation layer which are sequentially stacked along the first direction.

A solar cell including: substrate having front and back surfaces, the back surface includes first, second and gap regions, the first and second regions are alternately arranged and spaced from each other in a first direction, and a respective gap region is provided between adjacent first and second regions, first pyramidal texture structure regions are formed corresponding to gap regions and distance between top and bottom thereof is 2-4 m; first conductive layer formed over the first region; second conductive layer formed over the second region, the second conductive layer has conductivity type opposite to the first conductive layer; first electrode forming electrical contact with the first conductive layer; second electrode forming electrical contact with the second conductive layer; and boundary region between the gap region and the first and/or second conductive layer adjacent thereto, and the boundary region includes strip or line patterned texture structures arranged at intervals.

Provided are solar cell, preparation method thereof and photovoltaic module. Solar cell includes: segmented solar cells formed by segmenting same whole solar cell in first direction, whole solar cell has front surface and back surface oppositely arranged in second direction, each segmented solar cell has front sub-surface and back sub-surface oppositely arranged in second direction, front sub-surfaces of two segmented solar cells formed based on same solar cell are partial regions of front surface, and back sub-surfaces of two segmented solar cells formed based on same solar cell are partial regions of back surface; segmented solar cell has segmentation surface formed by segmentation, two angles supplementary to each other are formed between segmentation surface and plane where back sub-surface is located, and one angle is acute angle; and passivation layer at least located on segmentation surface. Present disclosure are beneficial to improving photoelectric conversion efficiency of solar cell including segmented solar cell.

A backside emitter solar cell structure having a heterojunction. On one side edge of the backside emitter solar cell structure having the heterojunction, on an edge region of a crystalline semiconductor substrate of the backside emitter solar cell structure having the heterojunction having a doping of a first conductivity type, there is a layer sequence with a double intrinsic layer formed.

A backside emitter solar cell structure having a heterojunction. On one side edge of the backside emitter solar cell structure having the heterojunction, on an edge region of a crystalline semiconductor substrate of the backside emitter solar cell structure having the heterojunction having a doping of a first conductivity type, there is a layer sequence with a double intrinsic layer formed.

An electrode assembly (100) for a solar cell. The electrode assembly comprises an insulating optically transparent film (101) comprising a plurality of perforations (103) formed therein, and a plurality of longitudinally extending, laterally spaced conductive wire portions (102) arranged side by side on a surface of the film. One or more of the perforations are formed so as to have at least a portion thereof interposed laterally between two wire portions of the plurality of wire portions. The perforations formed in the film may reduce losses that would otherwise occur due to absorption of light by the film. Also disclosed is a solar cell (107) that includes the electrode assembly described above, a method of forming the electrode assembly, a method of forming the solar cell, and a method of forming a solar module.

Methods of fabricating emitter regions of solar cells using surface treatments, and the resulting solar cells, are described herein. In an example, a method of fabricating a solar cell includes treating a surface of a silicon substrate to form a lyophilic area between two lyophobic areas and depositing a liquid phase material containing a silicon material in the lyophilic area to form an emitter region.

Methods of fabricating emitter regions of solar cells using surface treatments, and the resulting solar cells, are described herein. In an example, a method of fabricating a solar cell includes treating a surface of a silicon substrate to form a lyophilic area between two lyophobic areas and depositing a liquid phase material containing a silicon material in the lyophilic area to form an emitter region.