Indium Reduction in Bifacial Silicon Heterojunction Solar Cells with MoOx Hole Collector

IF 6.2 Q2 ENERGY & FUELS

Advanced Energy and Sustainability Research Pub Date : 2024-06-20 DOI:10.1002/aesr.202400105

Liqi Cao, Yifeng Zhao, Paul Procel Moya, Can Han, Katarina Kovačević, Engin Özkol, Miro Zeman, Luana Mazzarella, Olindo Isabella

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Abstract

Reducing indium consumption in transparent conductive oxide (TCO) layers is crucial for mass production of silicon heterojunction (SHJ) solar cells. In this contribution, optical simulation-assisted design and optimization of SHJ solar cells featuring MoO_x hole collectors with ultra-thin TCO layers is performed. Firstly, bifacial SHJ solar cells with MoO_x as the hole transport layer (HTL) and three types of n-contact as electron transport layer (ETL) are fabricated with 50 nm thick ITO on both sides. It is found that bilayer (nc-Si:H/a-Si:H) and trilayer (nc-SiO_x:H/nc-Si:H/a-Si:H) as n-contacts performed electronically and optically better than monolayer (a-Si:H) in bifacial SHJ cells, respectively. Then, as suggested by optical simulations, the same stack of tungsten-doped indium oxide (IWO) and optimized MgF₂ layers are applied on both sides of front/back-contacted SHJ solar cells. Devices endowed with 10 nm thick IWO and bilayer n-contact exhibit a certified efficiency of 21.66% and 20.66% when measured from MoO_x and n-contact side, respectively. Specifically, when illuminating from the MoO_x side, the short-circuit current density and the fill factor remain well above 40 mA cm⁻² and 77%, respectively. Compared to standard front/rear TCO thicknesses (75 nm/150 nm) deployed in monofacial SHJ solar cells, this represents over 90% TCO reduction. As for bifacial cells featuring 50 nm thick IWO layers, a champion device with a bilayer n-contact as ETL is obtained, which exhibits certified conversion efficiency of 23.25% and 22.75% when characterized from the MoO_x side and the n-layer side, respectively, with a bifaciality factor of 0.98. In general, by utilizing a n-type bilayer stack, bifaciality factor is above 0.96 and it can be further enhanced up to 0.99 by switching to a n-type trilayer stack. Again, compared to the aforementioned standard front/rear TCO thicknesses, this translates to a TCO reduction of more than 67%.

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带有氧化钼集孔器的双面硅异质结太阳能电池中的铟还原作用

减少透明导电氧化物（TCO）层中的铟消耗量对于硅异质结（SHJ）太阳能电池的大规模生产至关重要。在本论文中，采用光学模拟辅助设计和优化了以氧化钼空穴收集器和超薄 TCO 层为特征的 SHJ 太阳能电池。首先，以氧化钼作为空穴传输层（HTL），以三种类型的 n-触点作为电子传输层（ETL）的双面 SHJ 太阳能电池被制造出来，两面的 ITO 厚度均为 50 nm。研究发现，在双面 SHJ 电池中，双层（nc-Si:H/a-Si:H）和三层（nc-SiOx:H/nc-Si:H/a-Si:H）n-接面的电子和光学性能分别优于单层（a-Si:H）。然后，根据光学模拟的建议，在正面/背面接触式 SHJ 太阳能电池的两侧使用相同的掺钨氧化铟（IWO）层和优化的 MgF2 层。采用 10 nm 厚 IWO 和双层 n-contact 的器件，从氧化铟和 n-contact 面测量的认证效率分别为 21.66% 和 20.66%。具体来说，从氧化钼一侧照射时，短路电流密度和填充因子分别保持在 40 mA cm-2 和 77% 以上。与单面 SHJ 太阳能电池采用的标准前/后 TCO 厚度（75 nm/150 nm）相比，TCO 降低了 90% 以上。至于采用 50 nm 厚 IWO 层的双面电池，则获得了以双层 n-触点作为 ETL 的冠军器件，从氧化钼面和 n 层面看，其认证转换效率分别为 23.25% 和 22.75%，双面系数为 0.98。一般来说，利用 n 型双层叠层，双面系数可超过 0.96，而转换到 n 型三层叠层后，双面系数可进一步提高到 0.99。同样，与上述标准前/后 TCO 厚度相比，TCO 可减少 67% 以上。

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来源期刊

Advanced Energy and Sustainability Research

CiteScore

8.20

自引率

3.40%

发文量

期刊介绍： Advanced Energy and Sustainability Research is an open access academic journal that focuses on publishing high-quality peer-reviewed research articles in the areas of energy harvesting, conversion, storage, distribution, applications, ecology, climate change, water and environmental sciences, and related societal impacts. The journal provides readers with free access to influential scientific research that has undergone rigorous peer review, a common feature of all journals in the Advanced series. In addition to original research articles, the journal publishes opinion, editorial and review articles designed to meet the needs of a broad readership interested in energy and sustainability science and related fields. In addition, Advanced Energy and Sustainability Research is indexed in several abstracting and indexing services, including： CAS: Chemical Abstracts Service (ACS) Directory of Open Access Journals (DOAJ) Emerging Sources Citation Index (Clarivate Analytics) INSPEC (IET) Web of Science (Clarivate Analytics).