{"id":3522,"date":"2021-02-18T10:36:50","date_gmt":"2021-02-18T10:36:50","guid":{"rendered":"https:\/\/www.mub.eps.manchester.ac.uk\/science-engineering\/?p=3522"},"modified":"2023-06-21T09:19:18","modified_gmt":"2023-06-21T08:19:18","slug":"manchester-scientists-first-to-sequester-lead-in-solar-panels","status":"publish","type":"post","link":"https:\/\/www.mub.eps.manchester.ac.uk\/science-engineering\/2021\/02\/18\/manchester-scientists-first-to-sequester-lead-in-solar-panels\/","title":{"rendered":"University of Manchester scientists sequester lead in perovskite solar cells for the first time"},"content":{"rendered":"

Solar panels are becoming increasingly common in the UK, but their uptake needs to accelerate in order to supply enough green energy for the UK. Traditional silicon solar panels are efficient at converting sunlight to useful energy, but they can be quite expensive and impractical for some uses.<\/p>\n

This is where a newer form of solar panels may come in handy: perovskite solar cells.<\/p>\n

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These solar cells are becoming as efficient as silicon, yet differ in that they are made by simple solution processing and have the potential to be mass produced using roll-to-roll manufacturing, similar to the way newspapers are printed. This will drive the cost down significantly, making it more commercially viable to replace fossil fuel energy creation with solar energy.<\/p>\n

What\u2019s more, the perovskite cells can be made light and colourful, meaning they can be used in non-traditional settings like windows and on flimsy factory roofs so that buildings can power themselves.<\/p>\n

The problem with perovskite<\/h2>\n

A major drawback with the most efficient perovskite materials is that they contain lead, which is a cumulative toxin. If the perovskite cells get damaged, lead ions may leak – potentially causing environmental issues if lead ions are entrained into water courses.<\/p>\n

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