The cells and modules were truly black when they came out from production and had no signs of damage. Photo: Hele Savin's research group / Aalto University
A 2011 invention made by Aalto University’s researchers has proceeded from concept to reality. Just a few years ago, the researchers obtained the record efficiency of 22% in the lab for nanostructured solar cells using atomic layer deposition. Now with the help of industrial partners and joint European collaboration, the first prototype modules have been manufactured on an industrial production line.
'Our timing could not have been better,' Professor Hele Savin, who led the research, was pleased to share. Indeed, 2018 is commonly called the 'Year of Black Silicon' due to its rapid expansion in the photovoltaic (PV) industry. It has enabled the use of diamond-wire sawing in multicrystalline silicon, which reduces costs and environmental impact. However, there is still plenty of room for improvement as the current black silicon used in industry consists of shallow nanostructures that lead to sub-optimal optical properties and require a separate antireflection coating.
Aalto’s approach consists of using deep needle-like nanostructures to make an optically perfect surface that eliminates the need for the antireflection coatings. Their industrial production, however, was not an easy task. 'We were worried that such a fragile structure would not survive the multi-step mass production, because of rough handling by robots or module lamination.'
Luckily, the concerns were proven not to be an issue. The cells and modules were truly black when they came out from production and had no signs of damage. The best module was producing energy with more than 20% efficiency. In addition to excellent optical properties, the researchers were positively surprised that their black cells had additional unexpected benefits, such as a high tolerance towards impurities and much better long-term stability as compared to the industry standard reference cells.
Black PERC solar cell without AR-coating produced at industrial line. Obs. the substrate is multicyrstalline silicon despite the rounded corners. Photo: Hele Savin's research group / Aalto University
How expensive is black silicon technology? 'Questions related to techno-economical analysis are always difficult, especially for material scientists like us. Luckily, we got help from people with related expertise,“ Savin answers. The project partners provided data to Profesor Joshua Pearce at Michigan Tech University, whose preliminary calculations indicate that, while deep nanostructures are expensive to fabricate, the higher performance of the end product could balance out the total costs, e.g. due to a lower amount of process steps.
The R&D project (BLACK) was part of the Solar-ERANET network and was funded by the EU and Business Finland. The project partners included Spain’s Universitat Politècnica de Catalunya, Germany’s Solar World Innovations GmbH and Finnish-based companies Beneq, Naps Solar Systems, Cencorp, Okmetic, and Fortum. The project key findings will be presented by PhD student Toni Pasanen at the European Photovoltaic Solar Energy Conference in Brussels at the end of September 2018, where he will also receive an award in 'recognition of the most remarkable and outstanding research work in the field of PV'.
For further information, please contact:
Professor Hele Savin
tel. +358 50 541 0156
Toni P. Pasanen et al., ”Industrial applicability of AR-coating-free black silicon”, 35th European Photovoltaic Solar Energy Conference and Exhibition, September 24-28, 2018, Brussels, Belgium
Toni P. Pasanen et al., ”Elimination of light-induced degradation by black silicon” 35th European Photovoltaic Solar Energy Conference and Exhibition, September 24-28, 2018, Brussels, Belgium
Chiara Modanese et al., ” Dry-etched black silicon: A cost-effective production route for PERC solar cells”, 35th European Photovoltaic Solar Energy Conference and Exhibition, September 24-28, 2018, Brussels, Belgium
Toni P. Pasanen et al. “Black silicon significantly enhances phosphorus diffusion gettering”, Scientific Reports, 8, 1991:1–6 (2018).