Screen printed metal matrix composite contacts for crack tolerant solar cells

A. Manoussakis, Omar K. Abudayyeh, Nathan D. Gapp, D. Wilt
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引用次数: 1

Abstract

Solar cells used in space missions are the primary source for power on board the space vehicle. Space solar cells are becoming thinner for improved performance (W/kg) and are based on single crystalline materials where fracturing or cleaving can easily occur from packaging, deployment and constant temperature cycling in outer space. When the fracture in the semiconductor extends through the solar cell metallization, loss of power will occur and can hinder a mission. A novel semiconductor metallization is being developed that may enable the solar cells to be fully crack tolerant. The material consists of carbon nanotubes impregnated silver metallization, termed metal matrix composite, deposited by screen printing. The carbon nanotubes increase the fracture toughness of the metallization and also offers a redundant electrical path should the metal matrix fracture. In addition to these benefits, the use of screen printing will facilitate lower costs and ease of manufacturability by eliminating the expensive photolithography and evaporation steps used for conventional metallization. The inks that are being developed show promise of electrically bridging cracks and are further being tuned for screen printing processes.
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耐裂太阳能电池用丝网印刷金属基复合触点
在太空任务中使用的太阳能电池是太空飞行器的主要动力来源。太空太阳能电池正变得越来越薄,以提高性能(W/kg),并且基于单晶材料,在外层空间的包装、部署和恒温循环中很容易发生破裂或劈裂。当半导体中的断裂延伸到太阳能电池的金属化时,就会发生功率损失,从而阻碍任务的执行。一种新的半导体金属化技术正在开发中,它可能使太阳能电池具有完全的耐裂性。该材料由碳纳米管浸渍银金属化组成,称为金属基复合材料,通过丝网印刷沉积。碳纳米管提高了金属化层的断裂韧性,并在金属基体断裂时提供了冗余的电路径。除了这些好处,使用丝网印刷将有助于降低成本和易于制造,通过消除昂贵的光刻和蒸发步骤用于传统金属化。正在开发的油墨显示出电弥合裂缝的希望,并且正在进一步调整用于丝网印刷工艺。
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