Key Highlights
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Researchers have developed a new way to recycle plastic bottles (PET) into materials for high-performance solid-state batteries. This breakthrough tackles two major problems at once: reducing plastic waste and creating safer, more powerful electrolytes for next-generation energy storage.
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A new study reveals that the organic components inside popular perovskite solar cells can break down through irreversible chemical reactions when exposed to light or electrical current. Understanding and preventing this degradation is crucial for making these promising, low-cost solar cells last long enough for real-world use.
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Scientists have created a special 2D material that acts like a “lattice lock” to guide zinc metal to deposit in a perfectly flat, layered pattern inside batteries. This elegant solution prevents the formation of spiky, damaging zinc structures, paving the way for safer, longer-lasting, and more powerful zinc-based batteries.
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Engineers have developed a flexible, ultra-efficient triple-junction solar cell protected by ultrathin glass, making it tough enough for both harsh chemical environments and the radiation of space. This versatile technology could power future missions to other planets while also driving chemical reactions to produce fuels here on Earth.
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A detailed analysis of geothermal heat projects in the Netherlands shows that pumping cold water into underground rock layers can cause small earthquakes, but the risk is manageable. By carefully controlling the water temperature and understanding the local geology, we can harness Earth’s heat for clean energy with minimal seismic hazard.
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