研究人员在薄膜压缩红外光技术领域取得重要突破，揭示了该技术的三大创新优势，显著提升了实际应用潜力。研究团队证实：新型薄膜可令压缩后的红外光传播距离提升四倍以上；可作用于更宽泛的红外波段；同时具备优异的基材兼容性，能适应不同基底材料与复杂表面结构。

马德里卡洛斯三世大学（UC3M）与哈佛大学的联合科研团队取得重要突破，通过实验成功实现了对电磁超材料的可编程重构。这种创新性的人造材料无需改变其化学成分，即可重新编程其几何形状和结构行为。该项技术的问世，为生物医学和软体机器人等领域的创新发展提供了全新可能。

Researchers at Tohoku University have achieved record-breaking energy efficiency for a high-speed memory storage device, ...

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Nanoplastics are everywhere. These fragments are so tiny they can accumulate on bacteria and be taken up by plant roots; they ...