Indian scientists achieve record efficiency in new solar cells
Indian scientists have made a groundbreaking discovery in photovoltaics. Using tungsten disulfide, the new CIGS solar cell has achieved a record-breaking efficiency. Does this mean a revolution in solar energy harvesting?
10:33 AM EDT, September 26, 2024
Photovoltaics have been rapidly developing for years, but the latest discovery by scientists from the Visvesvaraya National Institute of Technology (VNIT) may set a new standard for this technology. The CIGS solar cell they developed is notable for its spectacular efficiency, flexibility, and resistance to high temperatures. This groundbreaking achievement has the potential to revolutionize the renewable energy market.
Solar cell with record efficiency
Scientists from India have made a breakthrough in solar cell technology. A research team from the Visvesvaraya National Institute of Technology (VNIT) developed a new CIGS photovoltaic cell that achieved an astounding efficiency of 25.7%, the highest ever recorded for this panel type.
The innovation involves the use of tungsten disulfide (WS2) as a back surface field (BSF) layer. This solution has significantly improved the efficiency of converting solar energy into electrical energy. CIGS cells, consisting of copper, indium, gallium, and selenium, have long been considered among the most promising in thin-film photovoltaics, but only now has such a high-efficiency level been achieved.
Will the new discovery revolutionize photovoltaics?
Scientists from India's discovery may significantly impact the future of photovoltaics. The introduction of tungsten disulfide (WS2) as a back layer increases the efficiency of CIGS solar cells and opens new possibilities for applying this technology. Thanks to their flexibility, these cells can be used in various products, such as roofs, building facades, or portable devices.
Additionally, the thin-film structure of CIGS cells, combined with their resistance to high temperatures, allows them to function better in harsh climatic conditions. Minimizing the use of rare elements like indium and gallium also reduces production costs, which may contribute to the popularization of solar cells on a larger scale.
Ultimately, if these cells enter mass production, it could revolutionize the way solar energy is harvested, both in terms of efficiency and cost.
