轻掺杂晶硅太阳电池正面银接触的微观结构表征

Z. Li, K. Mikeska, L. Liang, Andreas Meisel, Giuseppe Scardera, L. Cheng, P. Vernooy, M. Lewittes, M. Lu, F. Gao, L. Zhang, A. Carroll, Chun-Sheng Jiang
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引用次数: 7

摘要

晶体硅(c-Si)太阳能电池的全球年产量已达到约20吉瓦。材料科学的不断创新以及材料和加工成本的降低推动了这一领先技术的发展。这种创新的一个例子是逐步发展到更轻掺杂的发射器(LDE),以减少太阳能电池中的重组。前部(FS)金属化浆料的不断改进使这一进展能够降低串联电阻和提高电池效率。我们在这里报告了效率高达18.9%的均匀发射极LDE电池,用先进的FS银浆印刷。清楚地了解银触点和硅发射极之间界面区域的微观结构,以及LDE电池的相关导电机制,可以为提高整体效率和降低最终用户成本提供所需的指导。本文报道了利用扫描电子显微镜技术对FS银接触和轻掺杂发射极之间界面微观结构的最新研究。详细研究了纳米银胶体、界面玻璃、银晶等微观结构特征。讨论了LDE电池的微观结构、电池性能和电流传导机制之间的关系。
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Microstructural characterization of front-side Ag contact of crystalline Si solar cells with lightly doped emitter
Crystalline Si (c-Si) solar cell production has reached an annual scale of ~20 GW globally. Development of this leading technology has been boosted by continuous innovation in material science and reduced material and processing costs. An example of such innovation is the step-wise progression to more lightly doped emitters (LDE) that reduces recombination in the solar cell. Continuous improvement in front-side (FS) metallization pastes has enabled this progression to lower series resistance and higher cell efficiency. We report here homogeneous emitter LDE cells with efficiencies as high as 18.9%, printed with advanced FS Ag paste. A clear understanding of the microstructure of the interfacial region between Ag contact and Si emitter, and the associated electrical conduction mechanism of LDE cells can provide the guidance needed to drive overall efficiency higher and end-user cost lower. We report our latest investigation of the microstructure of the interface between FS Ag contact and lightly-doped emitter using scanning electron microscopy techniques. The microstructural features such as nano-Ag colloids, interfacial glass, and Ag crystallites are studied in detail. The relationship between microstructure, cell performance, and current conduction mechanism for LDE cells are discussed.
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