Magnetic Carbon Foam Adorned with Co/Fe Nanoneedles as an Efficient Activator of Oxone for Oxidative Environmental Remediation: Roles of Surficial and Chemical Enhancement

C Pub Date : 2023-11-13 DOI:10.3390/c9040107
Yi-Chun Chen, Xin-Yu Jiang, Bui Xuan Thanh, Jia-Yin Lin, Haitao Wang, Chao-Wei Huang, Hongta Yang, Afshin Ebrahimi, Sanya Sirivithayapakorn, Kun-Yi (Andrew) Lin
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Abstract

As heterogeneous catalysis is a practical method for activating Oxone, the immobilization of transition metals (e.g., Co, Fe) on carbonaceous supports is a promising platform. Thus, this study attempts to develop a carbon-supported metallic catalyst by growing Co/Fe on carbon foam (CF) via adopting melamine foam as a readily available template which could be transferred to nitrogen-doped CF with marcoporous structures. Specifically, a unique adornment of Co/Fe species on this CF is facilely fabricated through a complexation of Co/Fe with a plant extract, tannic acid, on melamine foam, followed by carbonization to produce nano-needle-like Co/Fe on N-doped CF, forming a magnetic CF (MCF). This resultant MCF exhibits a much higher surface area of 54.6 m2/g than CF (9.5 m2/g), and possesses a much larger specific capacitance of 9.7 F/g, than that of CF as 4.0 F/g. These superior features of MCF enable it to accelerate Oxone activation in order to degrade an emerging contaminant, bis(4-hydroxyphenyl)methanone (BHPM). Furthermore, MCF + Oxone exhibits a lower activation energy as 18.6 kJ/mol for BHPM elimination and retains its effectiveness in eliminating BHPM over multiple rounds. More importantly, the CF is also prepared and directly compared with the MCF to study the composition-structure-property relationship to provide valuable insights for further understanding of catalytic behaviors, surficial characteristics, and application of such a functional carbon material.
磁性碳泡沫修饰Co/Fe纳米针作为氧化环境修复的高效活化剂:表面增强和化学增强的作用
由于多相催化是激活氧酮的一种实用方法,过渡金属(如Co, Fe)在碳质载体上的固定化是一个很有前途的平台。因此,本研究试图采用三聚氰胺泡沫作为模板,在碳泡沫(CF)上生长Co/Fe,从而开发一种碳负载的金属催化剂,该模板可以转移到具有多孔结构的氮掺杂CF上。具体来说,通过将Co/Fe与植物提取物单宁酸在三聚氰胺泡沫上络合,然后碳化,在n掺杂的CF上产生纳米针状Co/Fe,形成磁性CF (MCF),可以很容易地在CF上形成独特的Co/Fe装饰物。所得的MCF的表面积为54.6 m2/g,远高于CF (9.5 m2/g),比电容为9.7 F/g,远高于CF的4.0 F/g。MCF的这些优越特性使其能够加速Oxone的活化,以降解新出现的污染物,双(4-羟基苯基)甲烷(BHPM)。此外,MCF + Oxone对BHPM的清除活化能较低,为18.6 kJ/mol,并且在多轮清除BHPM时保持有效性。更重要的是,我们还制备了CF,并将其与MCF进行了直接比较,研究了其组成-结构-性能关系,为进一步了解这种功能碳材料的催化行为、表面特性和应用提供了有价值的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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