Abstract
Aiming at the removal of refractory organic pollutants in aqueous solution, self-assembled nano-Fe3C embedded in reduced graphene oxide (nano-Fe3C@RGO) aerogel was prepared by hydrothermal synthesis and high temperature treatment, and characterized by SEM, HRTEM, pore size distribution, XRD, XPS and FTIR. The results showed that the aerogel was porous, and most of the Fe3C particles were less than 100 nm in size. They were evenly dispersed and embedded in the RGO aerogel. Furthermore, the mapping images confirmed that the elements of carbon, nitrogen and iron were homogeneously distributed. Moreover, the specific surface area of the aerogel was up to 324.770 m2/g and most of the pore sizes were between 5 and 10 nm. The formation of nano-Fe3C was identified by XRD pattern and HRTEM. Analysis of an XPS spectrum indicates that the nano-Fe3C was embedded in the graphene layer. The aerogel contained a large number of functional groups, including –NH2, –NH and –C=O, etc., which greatly strengthened the adsorption of organics. Finally, the Fenton-like catalytic degradation properties of the self-assembled nano-Fe3C@RGO aerogel were investigated by testing the removal of methyl orange from the aqueous solution. The results showed that the value of Ct/C0 decreased to 0.050 after 240 min, suggesting a high degradation rate was obtained. Meanwhile, the chemical reaction was verified in accordance with the first-order kinetic model, and the higher temperature was beneficial to the catalytic degradation. At the same time, methyl orange was degraded into small molecules by the hydroxyl and superoxide radicals generated during the reactions. Therefore, the self-assembled nano-Fe3C@RGO aerogel, as a novel Fenton-like catalyst, introduces a new approach in the field of treatment of refractory organic wastewater.
Highlights
In recent years, the Fenton process has become a promising wastewater treatment technology because of its strong oxidative ability and environmentally friendly nature
During the Fenton reaction, H2O2 is decomposed into hydroxyl radicals (HO·) under the catalysis of Fe2+ and the hydroxyl radicals are prone to react with organic pollutants
The self-assembled nano-Fe3C@RGO aerogel was prepared by hydrothermal synthesis and high-temperature treatment, and its Fenton-like catalysis properties and mechanisms were investigated in detail
Summary
The Fenton process has become a promising wastewater treatment technology because of its strong oxidative ability and environmentally friendly nature. The key to Fenton-like technology is the screening of carriers and the preparation of the supported catalyst. High specific surface area and corrosion resistance are required to catalyze carriers in Fenton-like technology. The RGO has a large specific surface area, excellent electron transfer capacity, and a pi-delocalized structure similar to that of benzene-like aromatic nucleus, which has good adsorption performance for organic compounds with aromatic nucleus. Fenton-like catalysts are mainly iron-based catalysts such as nanometer zero-valent iron [7,12–15], Fe2O3 [4,16–18], Fe3O4 [19–24], FeOOH [10,25–30], etc. Some of these catalysts are easy to oxidize, while others are easy to aggregate in the preparation process
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