纳米技术
表征(材料科学)
同步加速器
纳米尺度
同步辐射
材料科学
能量转换
一套
比例(比率)
工程物理
储能
工艺工程
降级(电信)
新兴技术
系统工程
计算机科学
化石燃料
纳米电子学
功率(物理)
能量(信号处理)
燃料电池
透视图(图形)
清洁能源
作者
Zhiqiang Wang,Linglong Han,Jin Zhou,Fusong Wang,Bin Ji,Longlong Fan,Zhe Ren,Shuo Wang,Weihan Li,Jian Peng,Wei Xu,Qingxi Yuan,Jing Zhang,Guangcai Chang,Xueliang Sun,Kang Dong
摘要
A comprehensive understanding of working and degradation mechanisms of energy materials is essential for enhancing their performance and tackling contemporary energy and environmental challenges, particularly in the transition from fossil fuels to renewables. Emerging nanoscale X-ray characterization techniques based on synchrotron radiation provide robust, multi-scale, and multi-modal analytical capabilities, making them a suite of powerful tools for revealing operational and failure mechanisms, especially of bulk materials with features ranging from nano to micrometers under realistic operating conditions. This Perspective initially highlights the advantages of X-ray methods based on synchrotron light sources and then summarizes X-ray-matter interactions and corresponding characterization methods. Three pivotal approaches that facilitate nanoscale X-ray imaging are subsequently summarized. Representative examples illustrate the versatility and power of these prominent techniques, including X-ray imaging, scattering/diffraction, and spectroscopy, in probing morphologies, compositions, atomic structures, and electronic properties. Integration of multi-scale and multi-modal X-ray techniques is underscored to achieve synergistic enhancements in analytical depth. It concludes with a discussion of current challenges, emerging opportunities, and future directions, providing insights into potential advancements in this field.
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