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用于可扩展有机光伏制造的印刷和涂层技术

Printing and Coating Techniques for Scalable Organic Photovoltaic Fabrication.

作者信息

Kirk Bradley P, Bjuggren Jonas M, Andersson Gunther G, Dastoor Paul, Andersson Mats R

机构信息

Flinders Institute for Nanoscale Science and Technology, College of Science and Engineering, Flinders University, Sturt Road, Bedford Park, Adelaide, SA 5042, Australia.

Centre for Organic Electronics, University of Newcastle, University Drive, Callaghan, NSW 2308, Australia.

出版信息

Materials (Basel). 2024 May 23;17(11):2511. doi: 10.3390/ma17112511.

DOI:10.3390/ma17112511
PMID:38893776
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11173114/
Abstract

Within recent years, there has been an increased interest towards organic photovoltaics (OPVs), especially with their significant device performance reaching beyond 19% since 2022. With these advances in the device performance of laboratory-scaled OPVs, there has also been more attention directed towards using printing and coating methods that are compatible with large-scale fabrication. Though large-area (>100 cm) OPVs have reached an efficiency of 15%, this is still behind that of laboratory-scale OPVs. There also needs to be more focus on determining strategies for improving the lifetime of OPVs that are suitable for scalable manufacturing, as well as methods for reducing material and manufacturing costs. In this paper, we compare several printing and coating methods that are employed to fabricate OPVs, with the main focus towards the deposition of the active layer. This includes a comparison of performances at laboratory (<1 cm), small (1-10 cm), medium (10-100 cm), and large (>100 cm) active area fabrications, encompassing devices that use scalable printing and coating methods for only the active layer, as well as "fully printed/coated" devices. The article also compares the research focus of each of the printing and coating techniques and predicts the general direction that scalable and large-scale OPVs will head towards.

摘要

近年来,人们对有机光伏(OPV)的兴趣日益浓厚,尤其是自2022年以来其显著的器件性能超过了19%。随着实验室规模的OPV器件性能取得这些进展,人们也更加关注使用与大规模制造兼容的印刷和涂层方法。尽管大面积(>100平方厘米)的OPV已达到15%的效率,但这仍落后于实验室规模的OPV。还需要更加关注确定适用于可扩展制造的提高OPV寿命的策略,以及降低材料和制造成本的方法。在本文中,我们比较了用于制造OPV的几种印刷和涂层方法,主要关注活性层的沉积。这包括在实验室(<1平方厘米)、小面积(1 - 10平方厘米)、中等面积(10 - 100平方厘米)和大面积(>100平方厘米)活性面积制造时的性能比较,涵盖仅对活性层使用可扩展印刷和涂层方法的器件,以及“全印刷/全涂层”器件。本文还比较了每种印刷和涂层技术的研究重点,并预测了可扩展和大规模OPV的总体发展方向。

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