High efficiency silicon and Germanium stack junction solar cells

Dongkyun Kim, Youngmoon Choi, E. Do, Yeonil Lee, Yun-Gi Kim
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引用次数: 2

Abstract

We have fabricated Si/Ge stack junction solar cells in order to overcome silicon single junction limit efficiency. Ge cell can absorb long wavelength photons that cannot be absorbed in Si. Bottom Ge solar cell can theoretically yield additional 5% efficiency to Si top cell. We have fabricated 21.3% top Si / 1.6% bottom Ge stack junction with 22.9% module efficiency. SiO2 and SiNx double insulating interlayers were optimized in order to transmit long wavelength photon to the Ge cell and achieve good passivation at the interlayer. The stack junction will be able to overcome the Si practical efficiency limit of 26% in the near future, and be the candidate for the next generation crystalline Si solar cell.
高效硅锗堆叠结太阳能电池
为了克服硅单结的效率限制,我们制作了硅/锗堆叠结太阳能电池。锗电池可以吸收硅不能吸收的长波光子。底部锗太阳能电池理论上比顶部硅太阳能电池多出5%的效率。我们制作了21.3%的顶部Si / 1.6%的底部Ge堆叠结,模块效率为22.9%。优化了SiO2和SiNx双绝缘中间层,使其能够向锗电池传输长波长光子,并在中间层处实现良好的钝化。在不久的将来,该叠层结将能够克服26%的硅实际效率限制,成为下一代晶体硅太阳能电池的候选材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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