Functionalized Nanomaterials for Catalytic Application. Группа авторов

Functionalized Nanomaterials for Catalytic Application - Группа авторов


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Fe when strengthened with other metals (transition) embedded in it, results in a redox reaction with catalytic decomposition, and is favored with the increase in efficacy of the electrocatalytic system to bring about degradation of TPs [53–55]. A figurative description of the functionalized catalytic activity is shown in Figure 1.3.

      In a typical report of Cui, L. et al., MO decomposition by H-EF was proved to be accelerated by FNM - Fe3O4/MWCNTs, when prepared by solvothermal process. Degradability of the TP was noted to be 90.3% (3 h) with reusability to 5 runs, at pH (3). This system with two compartments of FNM membrane required no external additives, but had a potency in green wastewater treatment techniques [56]. Zhao, H. et al. reported that Fe3O4@Fe2O3/ACA (activated C aerogel) as cathodic in this EF routine degraded (90%) of OP-pesticide imidacloprid (30 min) and TOC (60 min) in pH range of (3–9) [57]. Haber-Weiss model inferred that Fe2+ aided the decomposition of peroxide to form ·OH. ·OH and ·O2− contribute for the degradation of OP. Mesoporous FNMs MnCo2O4-CF (C felt) as cathodic EF with excellent porosity and large modified surface area prepared showed a powerful degrading capacity for CIP (100%) an antibiotic in 5 h and TOC (75%) in 6 h [58]. Mn2+/Mn3+, Co3+/Co2+ with e transfers enhanced peroxide decomposition to form ·OH and ·OOH required for five cycles degradation.

Schematic illustration of electro-Fenton functionalized catalytic degradative activity for water bodies.
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Librs.Net
FNMs as catalyst | Type | Year Process | Current/Voltage Parametric expressions Solution evolved (% degradation) | Reusable cycles Remarks Ref.
BGA-GDE | EF | 2019 Hydrothermal | 4.5 mA cm−2 pH (3–9) | 60 min BPA (~89.65%) | 5 TOC (~90%) | 5 · OH | pseudo-1st-order kinetics [62]
RGO-Ce/WO3 NS/CF | EF | 2018 Hydrothermal | 300–400 mA pH (3) | 1h CIP (100%) | 5 · O2−, H2O2, ·OH | Ce-WO3 improved adsorption [63]
ACF-HPC | EF | 2019 Hydrothermal, carbonization | (16, 20, 24) mA cm−2 pH (3, 7, 9) | 40, 180 min Phenol (93.8%) | 5TOC (85.7%) | 5 Enhanced formation of H2O2, ·OH | Low-cost [64]
Fe-C/PTFE | H-EF | 2015 Ultra-sonification | 100 mA pH (6.7) |120 min 2,4-DCP (95%) | pseudo-1st-order kinetics | promoters: H2O2, ·OH | Cheap [65]
N-C (NF) as (c PANI/GF2) | EF | 2019 Carbonization (PANI) |−0.6 V pH (3) |180 min Mineralization (42%) | Florfenicol (99%)| Phenol (85%) | MO (100%) | 5 Activation: H2O2·OH [66]
FeOx/NHPC750 | H-EF | 2020 Hydrothermal, carbonization | (−3.30, −4.42, −3.77) mA cm−2 | −0.6 V pH (6) |90 min ATZ (96%) | Rh B (99%) | 2,4-DCP (99%) | Sulfamethoxazole (95%) | Phenol (99%) | 5 Cleavage of O-O bond | Assists H2O2 | Fe2+ + O2 → Fe3+ + ·O2− [67]
Hydrothermal | 40 mA cm−2 pH (3) |360 min Bronopol (100%) |TOC (77%) | 3 Contributors: sunlight, ·OH, BDD (·OH) | [68]
Mn/Fe@porous C (PC)-CP cathode | H-EF | 2019 Carbonization | 40 mA pH (2–8) |120 min, 240 min TCS (100%) | TOC (~57%) | 6 Regeneration: Fe2+/Mn2+/3+| e-transfer: Fe2+/3+, Mn2+/3+/4+, pseudo-0-order kinetics [69]
3DG/Cu@C | H-EF | 2020 Hydrothermal, calcination | 30 mA pH (3–9) | 150 min Rh B (100%) | CIP (100%) | 2,4-DCP (100%) | PCA (89.8%) | BPA (96.1%) | CAP (82.6%) | 5 Contributors: ·OH, ·O2− | e- transfer: Cu2+/+ [70]
C felt/Fe-Oxides | H-EF | P-EF | 2016 Electro-deposition | 21.7 mA cm−2 pH (3) |120 min MG (98%) | 10 ·OH, BDD - activators | UVA | pseudo-1st-order kinetics | [71]
Hydrothermal | variable | −0.2 V pH (3) |180 min DMP (100%) | 20TOC (40.4%) Fe2+ + H2O2 → Fe3+ + e | pseudo-1st-order kinetics [72]
F-rGO/SS membrane | EF | 2019 Electrophoretic deposition | 170 mA | −0.5 V pH (3) | PCM (37%) | 5 e- transfer-enhanced by rGO | low-cost membrane [73]
G-CNT-CE | EF | 2014 Electrophoretic deposition | 0.18 A pH (3) |210 min Acid Red 14 (91.22%) |Acid Blue 92 (93.45%)