Lithuanian researchers created new materials that might increase the stability of perovskite solar cells
A group of chemists from Kaunas University of Technology in Lithuania, the authors of numerous breakthrough innovations in the solar energy field, proposed yet another solution to increase the stability and performance of perovskite solar elements.
KAUNAS UNIVERSITY OF TECHNOLOGY
Cross-linking effect provides resistance to the new compounds synthesised by Lithuanian chemists view more
Credit: And Unicorns
A group of chemists from Kaunas University of Technology in Lithuania, the authors of numerous breakthrough innovations in the solar energy field, proposed yet another solution to increase the stability and performance of perovskite solar elements. They synthesised a new class of carbazole-based cross-linkable materials, which are resistant to various environmental effects, including strong solvents used in the production of solar cells.
When applied as hole transporting layers, the new materials developed at Kaunas University of Technology (KTU) labs, helped achieve the 16.9% efficiency of the inverted-architecture perovskite cells at the first attempt. It is expected to reach higher efficiency upon optimisation.
New materials thermally polymerised to provide resistance
Organic-inorganic hybrid perovskite solar cells have been attracting worldwide attention as a competitive alternative to conventional silicon-based solar technologies. They are cheaper, more flexible and have higher power conversion efficiency. Scientists all over the world are working to solve challenges related to improving the stability and other features of the perovskite solar elements. These layered, new generation solar cells can have two architectonic structures – regular (n-i-p) and inverted (p-i-n) structures. In the latter, the hole transporting materials are deposited under the perovskite absorber layer.
“Although p-i-n cells have numerous advantages when compared to the perovskite solar cells of regular architecture, they have serious shortcomings. For instance, the hole transporting compounds should be able to withstand the strong polar solvents used to form light-absorbing perovskite layer, which is placed above,” explains Professor Vytautas Getautis, chief researcher at KTU Faculty of Chemical Technology.
To solve this problem, in p-i-n architectures polymers are often used as hole transporting materials. However, due to solubility issues, a polymer layer is not easy to form; moreover, it is difficult to control the recurrence of reactions and synthesise the same structure. Aiming to solve this issue, KTU researchers made a hole transporting layer of carbazole-based molecules, which then was thermally polymerized in situ to reach cross-linking effect.
“The cross-linked polymer has a three-dimensional structure. It is very resistant to various effects, including the strong solvents used while forming a light-absorbing perovskite layer. We used several groups of molecules and developed materials, which, while used as a hole transporting layer, can improve the efficiency of an inverted perovskite solar cell to almost 17 per cent,” says a PhD student Šarūnė Daškevičiūtė-Gegužienė, who synthesised these compounds.
The above-described invention was featured as a cover article in Chemical Communications, published by the Royal Society of Chemistry, UK. The cover image was created by And Unicorns, a Lithuanian design company.
Authoring record-breaking tandem solar cell
The research group headed by Prof Getautis has developed numerous cutting-edge inventions, aimed at improving the efficiency of solar cells. Among them are synthesised compounds, which self-assemble into a molecule-thin layer that acts as a hole transporting material. The silicone-perovskite tandem solar produced using the said materials reached an efficiency of over 29 per cent. According to Prof Getautis, the latter tandem combination will soon become the commercially available alternative to silicone-based solar cells – more efficient and cheaper.
“Our field of research aims to improve the existing technologies for perovskite solar elements and in this field, we have achieved the best results with the self-assembling-monolayer technology. However, science is often developed in multiple directions, as we need to explore ways to use solar energy the best we can,” says Prof Getautis.
Although perovskite cells are a novelty compared to silicone-based solar technologies, there are several companies which have already commercialised different products based on perovskite technology. Among them are flexible semi-transparent interior elements, wearable electronics to control the wildlife population, and various architectural solutions. And this is just the beginning.
According to Prof Getautis, of all renewables, solar energy has the largest potential and is the least exploited. However, thanks to the new research, this field is developing exponentially. It is estimated that by 2050, around half of the electricity used on earth will be produced from solar energy.
“Solar energy is entirely green – it is pollution-free, and the installed solar farms don’t require much maintenance. Keeping in mind current events, and the energy crisis, more and more people are interested in installing solar power plants in their homes or owing a share of a solar farm. It is a future of energy,” Prof Getautis is convinced.
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