Warwick University has been granted £2.2 million (over USD$2,620,000) to investigate metal halide perovskite compounds, for use in transparent and flexible solar panels, which remain stable in space. A new Nuclear Magnetic Resonance (NMR) spectrometer will be used to understand how to increase lifespan and durability of these solar cells.
The European Research Council (ERC) has approved a five-year study which will explore the atomic-level structure of perovskite solar cell materials. This will address issues including stability and lifespan of metal halide perovskite compounds, which decrease in high humidity, strong sunlight and at elevated temperatures.
Interestingly, while the properties of perovskite solar cells change in a range of atmospheric conditions, they remain remarkably stable outside the Earth's atmosphere. This points to the potential for harvesting energy in space – a topical area of research, after the European Space Agency revealed it would be investigating whether satellites could beam electricity back to Earth earlier this year.
Using Nuclear Magnetic Resonance (NMR– an analytical chemistry technique that harnesses high magnetic fields and radiofrequencies targeted at atomic nuclei) scientists hope to better understand what is causing this type of solar cell material to degrade at the atomic level.
The ERC Starting Grant of £2.2 million will involve the purchase of a 400 MHz solid-state NMR spectrometer worth £0.9 million, with unique capabilities that are currently hard to access. It will be installed specifically for this project, enabling researchers to investigate the atomic-level structure of solar cells. The eventual aim is to help improve the durability of these devices, so they can be relied on for decades to come.
The research will be led by Drץ Dominik J. Kubicki, an Assistant Professor in the Department of Physics, University of Warwick. He said: “This study will help diversify sustainable energy sources and explore more options in the quest to reduce reliance on fossil fuels. We’re keen to understand more about why these solar cells degrade in different atmospheric conditions at the atomic level, so we can design new, better materials and ensure maximum efficiency of this new sustainable energy source. Silicone is the current material used in solar cells and while those devices have a long durability of over 20 years, they have certain limitations. Solar cells need to be relatively thick; silicon is brittle, and it succumbs to cosmic radiation. Metal halide perovskites enable us to overcome these limitations, diversify the ways in which we can harvest solar energy, and apply them in contexts we had not previously anticipated. Investigating these materials will be very exciting, and we hope to find out how to make them more stable.”
