A. Upadhyaya, Y. Ok, E. Chang, V. Upadhyaya, Keeya Madani, K. Tate, Eunhwan Cho, B. Rounsaville, V. Chandrasekaran, V. Yelundur, Atul Gupta, A. Rohatgi
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引用次数: 4
摘要
本文介绍了一种具有p+和n+覆盖层的21% n - cz 239cm2丝网印刷电池的结果和局限性。此外,我们还展示了在背面掺杂n+多晶硅和金属的隧道氧化物的性能和影响,可以克服这些限制。由于掺杂的n+层和金属触点都在硅晶片的外部,因此Jo急剧减少,从而导致更高的Voc。工艺优化后,对称结构的iVoc高达728mV。采用Al2O3/SiN钝化轻掺杂p+发射极和隧道氧化物/n+聚背的非金属化电池结构也获得了727mV的高iVoc。完成的132cm2丝网印刷器件的Voc为683mV, Jsc为39.4mA/cm2, FF为77.6%,效率为20.9%。电池分析表明,选择性发射极的实现可以提供更高的效率。
Ion implanted screen printed N-type solar cell with tunnel oxide passivated back contact
This paper shows the results and the limitations of a 21% N-Cz 239cm2 screen printed cell with blanket p+ and n+. In addition, we show the properties and impact of tunnel oxide capped with doped n+ polysilicon and metal on the back side which can overcome those limitations. Since both the doped n+ layer and the metal contact are outside the bulk silicon wafer, the Jo is dramatically reduced resulting in much higher Voc. Process optimization resulted in high iVoc of 728mV on the symmetric structures. The un-metallized cell structure with Al2O3/SiN passivated lightly doped p+ emitter and a tunnel oxide/n+ poly back also gave high iVoc of 727mV. The finished screen-printed 132cm2 device gave a Voc of 683mV, Jsc of 39.4mA/cm2, FF of 77.6% and an efficiency of 20.9%. Cell analysis show that implementation of a selective emitter can give higher efficiency.
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