Functionalized Nanomaterials for Catalytic Application. Группа авторов

Functionalized Nanomaterials for Catalytic Application - Группа авторов


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kinetics | pseudo-2nd-order kinetics [74] Fc-ErGO | EF | 2018 Electrochemical | −1.5 V | (−0.75, −1.0, −1.5, −2.5) V pH (3) | 15 min | pH (7) | 120 Min CIP (99%) | 5 ·OH | pseudo-1st-order kinetics [75] FeOCl-CNT | EF | 2020 Thermal-induced | −0.8 V pH (wide) | TC (99.5%) | Fe3+/Fe2+ | H2O2 + ·OH → H2O + ·OOH [76] 3D GA/Ti wire | EF | 2018 Hydrothermal | [0 – (−95.5)] mA cm−2 pH (2) |120 min EDTA-Ni (m73.2%) | 5 π-π interaction | pseudo-1st- order kinetics [77]

Schematic illustration of functionalized nanomaterials as photo-Fenton catalyst for water resource management.

      1.4.1 Heterogenous-Fentons-Based FNMs

      FNM PAN with EDC as catalyst was used to study the regeneration efficiency of the material in use, by the experimentalist. Further, the regenerated catalytic reaction as heterogenous Fenton (HF) was found to be a better option for degrading RO-16 [80]. Living species vulnerable to the revelation of pharmaceutical organic lteftovers in the water system causing ecological barriers was the point of attack by reporters Wan, Z. et al. [81]. Fe3O4-Mn3O4/RGO synthesized by polyol and impregnation processes worked well as a HF-like catalyst with the actively formed OH, decomposed SMT (sulfamethazine-drug) (99%/50 min) effectively in a water solvent. Authors Zhou, L. et al., forecasted that the drawbacks due to catalytic reactions can be knocked off by using MPCMSs [82]. C micro-spheres protected Fe3O4 NM from oxidation, while degrading MB. Formation of ·OH supported this HF reaction by H2O2 and NH2OH.

      1.4.2 Photo-Fentons-Based FNMs

      Feox NPs/D3 (diamond NP) that worked well as a H-PF catalyst was effective in degrading and decomposing phenol and H2O2, respectively, under an ambient condition. Later, was proved to be a better alternative when in comparison with its analogous as per reports of Espinosa, J.C. et al., where phenol acts as h+ quencher and diamond NP as surface releaser of ·OH favors the optimized reaction [83]. Upgraded new water treatment competencies are scaling up in saving the water resources. For instance, a low-cost valuable functionalized M (magnetite)/PEG/[(FeO (Iron III oxlate)/FeC (Iron III citrate)] showed high catalyst action for a quick disposal and degradation of BPA. Later, the evidenced PF catalyst when on exposing the chosen probe with UV-A light/H2O2, had a hierarchical degradation as (M/PEG/FeO) (15 min) > (M/PEG/FeC) > (M/PEG) [84]. In one of their work, a comparative study of MB degrading effect by the synthesized supports of Ni foam (NiF) and Ceramic foam (CM) was done by the authors, whose reports infer that the order of decomposing capacities were: (NiF/TiO2) > (CM/TiO2) > (NiF/Bi2 WO6) > (CM/Bi2WO6). In the same manner, decomposition of Rh B was studied using NF/TiO2 for PF reactions [85].

      In a different situation, reporters Bui, V.K.H. et al., revealed that Mg-AC (Mg amino-clay) with its versatility and unique characteristic, along with other 2D resources, have fascinated researchers [86]. Hence, Mg-AC finds its place and with a commendable performance in various fields especially in water resources. The resourceful material MgAC-Fe3O4/TiO2 works best for PF catalytic decomposition of MB (93%) (20 min), where ·OH and ·O2− formed are promoters for the redox-reaction. Cost-effective and potential approach with Fe-HPAN (carboxyl) functionalized beads developed by researchers was exposed for an effective PF catalytic reaction. Their results showed a better degrading capacity of 99.78% for TOC and 91.68% for p-nitrophenol removal and profitable reutilization was supported by the mesopores present in the FNM [87].


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