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Size-Dependent Oxidation-Induced Phase Engineering for MOFs Derivatives Via Spatial Confinement Strategy Toward Enhanced Microwave Absorption
Nano-Micro Letters ( IF 26.6 ) Pub Date : 2022-04-12 , DOI: 10.1007/s40820-022-00841-5 Hanxiao Xu 1 , Guozheng Zhang 1 , Yi Wang 1 , Mingqiang Ning 2 , Bo Ouyang 3 , Yang Zhao 4 , Ying Huang 1 , Panbo Liu 1
中文翻译:
MOF 衍生物的尺寸依赖性氧化诱导相工程通过空间限制策略增强微波吸收
更新日期:2022-04-12
Nano-Micro Letters ( IF 26.6 ) Pub Date : 2022-04-12 , DOI: 10.1007/s40820-022-00841-5 Hanxiao Xu 1 , Guozheng Zhang 1 , Yi Wang 1 , Mingqiang Ning 2 , Bo Ouyang 3 , Yang Zhao 4 , Ying Huang 1 , Panbo Liu 1
Affiliation
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The size of metal organic frameworks (MOFs) derivatives was manipulated by a spatial confined growth strategy.
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Dielectric polarization is the dominant dissipation mechanism due to the phase hybridization based on size dependent oxidation motion.
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The specific reflection loss of synthesized Co/Co3O4 hollow carbon nanocages surpasses most reported MOFs derived counterparts for practical microwave absorption applications.
中文翻译:
MOF 衍生物的尺寸依赖性氧化诱导相工程通过空间限制策略增强微波吸收
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金属有机骨架 (MOF) 衍生物的尺寸由空间限制生长策略控制。
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由于基于尺寸依赖性氧化运动的相杂化,介电极化是主要的耗散机制。
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合成的 Co/Co 3 O 4中空碳纳米笼的特定反射损耗超过了大多数报道的 MOF 衍生的用于实际微波吸收应用的对应物。
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