Functionalized Nanomaterials for Catalytic Application. Группа авторов

Functionalized Nanomaterials for Catalytic Application - Группа авторов


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[155]. While, straddling, staggered, and broken heterojunctions belonging to type 1, type 2, or type 3, with a small/large bandgap between CB and VB/or CB and VB with high potentials, are used in ZnO/g-C3N4 [156], Bi/Bi2WO6/g-C3N4 | Bi/Bi2MoO6/g-C3N4 [157], SmVO4/g-C3N4 [158], g-C3N4/CuWO4 [159], and BiVO4/g-C3N4 [160]. Thus, many FNMs have been used in fabrication, to name a few for the removal of organic toxics like MB, MO, Rh B, fuchsin, and X3B form water segments.

      Li, H. et al., fabricated WO3/Cu/g-C3N4 nanohybrids to degrade 4-nonylphenol [161]. While, Yang, Y. et al. used Ag@AgBr/g-C3N4 FNMs as nano-composites to degrade MO [162]. Similarly, the authors Fu, J., et al., in their recent publication of CdS/g-C3N4, demonstrated a comparable output in enhancement-factor as 20.5 and 3.1 for dye-degradation of MO while using the composites of two active semiconductors g-C3N4 and CdS individually [163]. Later, in another experiment, the authors Yang, Y. et al. investigated SPR results of Ag NMs while studying the performance of Ag-coated-g-C3N4 over MO dye-degradation [164]. In another situation, researchers Ma, D. et al. revealed that g-C3N4/RGO/Bi2WO6 FNMs that fit the Z-scheme had RGO as a bridge to transfer the e electrons between the two bands g-C3N4 and Bi2WO6. The photoelectrons formed in the CB of the later Bi2WO6 moves rapidly into the VB of the former g-C3N4 (holes) to accumulate sufficient (e) electrons in the CB of the former and holes of VB in the later. FNMs were found effective to photocatalytically degrade and remove TCP from water [165].

       1.5.1.5 Graphene-Carbon Nitride/QD-Based FNMs

      Hydrothermally synthesized BWO fixed as ultrathin Bi2WO6 NSs embedded on g-C3N4 QDs as (CNQDs/BWO), belonging to Z-scheme, efficiently degraded organic contaminants of antibiotic TC and dye Rh B, with % efficacy of 92.51 and 87 in NIR and visible regions, in ~1 h. Langmuir-Hinshelwood model adopted by the authors Zhang, M. et al. later showed that the bandgap energy of 2.70 eV (BWO) and 2.60 eV (CNQDs) was sufficient to bring the change [168]. The authors Zhou, L. et al., proved that GCNQD-treasured on modified g-C3N4 had a worthy photocatalytic degrading activity against organic Rh B [169]. The experimentalists Lin, X. et al. observed that hydrothermally synthesized nano-heterostructures of CNQDs/InVO4/BiVO4 on a leaf-like material of InVO4/BiVO4 had ·O2− radical as the main force behind the efficient oxidative-degradation of Rh B organic dye [170].

      Similarly, heterostructure GCNQDs/Ag/Bi2MoO6 NSs had a very good 100% degrading capability of Rh B in visible region, where h+ of VB (Bi2MoO6) and e of CB (CNQDs) worked effectively for oxidation/reduction to cause degrading reaction to give H2O and CO2 [171]. Si NWs (silicon nano-wires) on g-C3N4 QDs as Si NWs @ g-CNQDs, photoelectrocatalytically could decompose 85.1% of 4-CP in ~ 2 h from aqueous solution, had a notable charge separation and good stability [172]. π-conjugated GCNQDs implanted on metalloid sulfide Sb2S3/supported by ultrathin-g-C3N4, with a bandgap of 2.7 eV, were proved to be good candidate for photocatalytic disposals of MO from unwanted water and had a very good electron (e) transference [173]. In a novel approach, the co-workers Patel, J. et al. synthesized Mn:ZnS/QDs, for photo-degrading fluoroquinolone: Norfloxacin in an ambient condition of solar-light/UV-light, where Mn and ·OH fortified the reaction to 4 reapplied cycles [174].

      1.5.2 Polymer Composite–Based FNMs as Photocatalysts

      Polymer TiO2/CS/glass FNMs were powerful in decomposing RR4 organic dye in visible region. h+ and ·OH generated from TiO2 layer circulate to TiO2/CS boundary to cause oxidation of RR4. A total of 100% efficiency was noticed with the stability up to seven reusable cycles [175]. CdS/TiO2-PAN FNM degraded MB (66.29%) in 210 min [176]. Researchers studied the photocatalytic action and inferred a repeated utility to protect the water system. Chitosan-AgCl/Ag/TiO2 synthesized by the team Jbeli, A. et al. was reported to be cost-effective photocatalytic degrader of organic components ABA, O-TD, and SA under visible radiations [177]. Similarly, surface modified FNM TiO2/ZnO/chitosan had a powerful photo-degradability of MO (97%) when excited by solar radiations [178]. An organic/inorganic FNM as composites P3HT/PNP-Au NP got by re-precipitation method showed positive spectral line in UV region (~427 nm), had an enhanced photocatalytic decomposition of MB (90.6%), and inferred that it may be due to a strong π-π* shift [179]. A 3D honey-comb like ordered macro-porous NM-3DOM Ag/ZrO2 had significant photocatalytic degradability over CR when stimulated by multi-modules of microwave-assisted, simulated-solar, UV, and visible radiation [180].

      1.5.3 Metal/Metal Oxide-Based FNMs as Photocatalysts

      FNMs as nanocatalyst have been authenticated with a promising note for cleansing and sanitization treatment for a mixture of waste and normal water from different sources. With an excellent potentiality to inactivate the active disease-causing dreadful pathogenic micro-organisms like fungi, bacteria, and viruses, FNMs behold their role to safeguard the water bodies. Increase in the potential momentum for anti-microbial activity is efficaciously observed by surface


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