Key Highlights
- The behavior of molten fluoride salts, crucial for nuclear reactors and metal production, is governed by a property called “fluoroacidity,” which describes how fluoride ions coordinate with metals. Understanding this link between microscopic structure and large-scale properties creates a powerful framework for designing safer and more efficient industrial processes.
Source → - Ion movement within perovskite solar cells is a major factor influencing both their high performance and their tendency to degrade over time. By studying how these ions move and developing ways to control them, scientists aim to create solar cells that are both more powerful and longer-lasting.
Source → - A major hurdle for solid-state batteries is getting lithium ions to move quickly through the solid electrode material. New research focuses on overcoming this transport limitation, which is key to unlocking batteries with higher energy, faster charging, and improved safety.
Source → - Scientists are building tiny, programmable machines out of DNA that can perform tasks like delivering drugs or detecting diseases. The future of this technology depends on optimizing key features like how fast they move, how much force they generate, and how efficiently they operate on their own.
Source → - A special class of plastics, known as Covalent Adaptable Networks, can be reshaped and recycled because their molecular crosslinks can break and reform under certain conditions. This “reprocessability” offers a sustainable path forward for creating durable yet recyclable polymer materials, reducing plastic waste.
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