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The Belgian Microelectronics Research Center (Imec) and Schott Solar, Total, Photovoltech, GDF-SUEZ, Solland Sola, Kaneka, and Dow Corning collaborated to show the conversion rate of 23.3% fork-back contact (IBC) Solar silicon battery.
According to Imec, the introduction of the interdigitated back contact technology aims to increase the conversion efficiency of crystalline silicon solar cells, further reducing the thickness of the cells, simplifying the manufacture of modules, and beautifying solar cell modules.
Imec said that its multi-collaborative solar silicon cell industry affiliate program aims to increase the cell conversion efficiency to more than 20% and adopt a more advanced method to reduce the cost of solar silicon cells. Currently, as part of the program, it has developed an efficient basic process for small IBC batteries.
Recent key factors for the development of small (2cm*2cm) IBC solar silicon cells include: n-type FZ silicon substrates, random pyramid textures, boron emitters, simultaneous diffusion of phosphorus back surface field,
Thermally grown silicon dioxide, silicon nitride single-layer anti-reflective coating for surface passivation, lithographic patterning and aluminum powder coating.
Based on the application of the above technologies, the IBC battery achieves a conversion efficiency of 23.3% in the designated area. (Jsc = 41.6 mA, Voc = 696 mV, FF = 80.4%) and certified by ISE-Callabs.
Jef Poortmans, director of Imec Photovoltaic R&D Program, said: "We are very pleased to demonstrate the high conversion rate achieved on IBC solar cells. The high conversion rate of small IBC solar cells will lay a foundation for future large-scale IBC battery technology suitable for the industrial industry. The foundation for persistence.(Translation: Erin)
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