材料科学
电子结构
晶界
应变工程
表征(材料科学)
纳米材料基催化剂
纳米晶
纳米技术
化学物理
变形(气象学)
拉伤
材料设计
光谱学
延展性(地球科学)
密度泛函理论
凝聚态物理
延伸率
材料性能
剪切模量
结晶学
剪切(地质)
粒度
电子能量损失谱
纹理(宇宙学)
分子动力学
应变能
作者
Min Gee Cho,Colin Ophus,Jung-Hoon Lee,Inchul Park,Dong Young Chung,Jeong Hyun Kim,Dokyoon Kim,Yung‐Eun Sung,Kisuk Kang,Mary Scott,A. Paul Alivisatos,Taeghwan Hyeon,Myoung Hwan Oh
标识
DOI:10.1021/acs.chemmater.5c01154
摘要
Engineering grain boundary (GB) strain provides a promising pathway to tune the catalytic properties of nanocrystals. However, structural heterogeneity from random grain orientation and geometry has limited clear structure–property correlations. Here, we utilize a multigrain Co3O4/Mn3O4 core/shell nanocrystal platform as a model system to systematically investigate how geometric misfit strain at GBs serves as catalytically active sites for the oxygen reduction reaction. Through precise subnanometer-level control over grain morphology and by integrating multiscale electronic structure characterization, we identify the electronic structural signature of GB defects and establish a direct correlation between localized strain fields and modified electronic states. Strain modulation at GBs alters the eg orbital energy levels, with elongation along the z-axis combined with shear strain stabilizing the eg states, in contrast to the destabilization observed under pure shear strain. This stabilization mechanism enhances the electrocatalytic activity and selectivity of strained GBs compared with strain-relaxed grain surfaces. Furthermore, we reveal that GBs exhibit a radial strain gradient, producing a spatial energy shift that further modulates local electronic structures, as resolved through the classification of electron energy loss spectroscopy data. Together, these findings demonstrate that geometric misfit strain enables precise tuning of grain geometry and the resulting electronic structures, offering a robust strategy for engineering next-generation nanocatalysts.
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