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Learning from existing photovoltaic technologies to identify alternative perovskite module designs

机译:从现有的光伏技术学习识别替代佩洛斯库特模块设计

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摘要

Perovskite solar cells have now become the most efficient of all multicrystalline thin film photovoltaic technologies, reaching 25.2% in 2019. This outstanding figure of merit has only been achieved on small lab-scale devices, with significantly lower performance when processed on larger more industrially relevant substrate sizes. Perovskite modules, connecting several smaller area cells together, are commonly demonstrated with a superstrate monolithic interconnection method. However, several other module designs exist and remain largely unexplored by the perovskite community. In this work, we review and highlight those alternatives and discuss their advantages and limitations. We propose that a singulated substrate-oriented module design, using metallic substrates, could provide a quicker path to seeing highly efficient, lightweight, and flexible perovskite modules on the market, while mitigating near-term technical risks. As an experimental starting-point towards this design, we demonstrate a substrate-oriented all-perovskite 2-terminal tandem with 18% efficiency.
机译:Perovskite太阳能电池现在已成为所有多晶硅薄膜光伏技术的最有效,2019年达到25.2%。这个优秀的优点上仅在小型实验室规模的设备上实现了,在更大的工业上加工时的性能显着降低衬底尺寸。将多个较小的区域电池连接在一起,普遍存在的单片互连方法普遍证明钙钛矿模块。但是,佩洛斯库特社区存在几个其他模块设计,并仍然很大程度上是未开发的。在这项工作中,我们审查并突出这些替代方案并讨论其优势和局限性。我们提出了一种使用金属基板的定义面向基板的模块设计,可以提供更快的路径,以便在市场上看到高效,轻质和柔性的钙钛矿模块,同时减轻近期技术风险。作为这种设计的实验起点,我们展示了基板导向的全钙钛矿2末端串联,效率为18%。

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  • 来源
    《Energy & environmental science》 |2020年第10期|3393-3403|共11页
  • 作者

    Werner Jeremie; Boyd Caleb C.; Moot Taylor; Wolf Eli J.; France Ryan M.; Johnson Samuel A.; van Hest Maikel F. A. M.; Luther Joseph M.; Zhu Kai; Berry Joseph J.; McGehee Michael D.;

  • 作者单位

    Univ Colorado Chem & Biol Engn Boulder CO 80309 USA|Natl Renewable Energy Lab 15013 Denver West Pkwy Golden CO 80401 USA;

    Natl Renewable Energy Lab 15013 Denver West Pkwy Golden CO 80401 USA|Stanford Univ Mat Sci & Engn Stanford CA 94305 USA;

    Natl Renewable Energy Lab 15013 Denver West Pkwy Golden CO 80401 USA;

    Natl Renewable Energy Lab 15013 Denver West Pkwy Golden CO 80401 USA|Stanford Univ Dept Appl Phys Stanford CA 94305 USA;

    Natl Renewable Energy Lab 15013 Denver West Pkwy Golden CO 80401 USA;

    Univ Colorado Mat Sci & Engn Boulder CO 80309 USA;

    Natl Renewable Energy Lab 15013 Denver West Pkwy Golden CO 80401 USA;

    Natl Renewable Energy Lab 15013 Denver West Pkwy Golden CO 80401 USA;

    Natl Renewable Energy Lab 15013 Denver West Pkwy Golden CO 80401 USA;

    Natl Renewable Energy Lab 15013 Denver West Pkwy Golden CO 80401 USA;

    Univ Colorado Chem & Biol Engn Boulder CO 80309 USA|Natl Renewable Energy Lab 15013 Denver West Pkwy Golden CO 80401 USA|Univ Colorado Mat Sci & Engn Boulder CO 80309 USA;

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