Functionalized Nanomaterials for Catalytic Application. Группа авторов

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[97] Zn0.94 Fe_0.04S/g-C₃N₄ | PF | 2020 Microwave| Hydrothermal Solar light pH (6.1) | 60 min 4-NP (96%) |TOC (55.4%) | 5 CB favors e⁻ transfer Fe³⁺ → Fe²⁺ + e⁻ [98] Cu-FeOOH/CNNS(g-C₃N₄) | PF | 2018 Simple thermal Solar light pH (4.8-10.1) | 40 min | pH (low) MB | Rh B | MO | CR | 4-NP | TC | ~90% (OP) | 10 H₂O₂ + e⁻ → 2 ^·OH ^· O²⁻ | ^·OH (Scavengers) | pH (low) efficient [99] (Fe-CS/MMTNS | PF | 2020 Sol gel (3 Step) Visible light pH (3,6,10) | 2 h MB (55.81%) | 5 ^·OOH | ^·O²⁻ | activators | n → π*| π → π* - transition [100] Fe⁰)/MnO_x/BiVO₄ | PF | 2019 Hydrothermal | Photo-deposition Visible light pH (acidic) | 30 min 2,4-di-CP (95.4%) | BPA (91.4%) | 4 Rate of reaction ^·OH > h⁺ > ^·O²⁻ | bandgap (2.10 eV) [101] GO/MIL-88A(Fe) | PF | (2020) Vacuum-filtration Visible light - | 40 min MB (98.81%) | BPA (97.27%) |12 ^·OH > ^·O²⁻ >>h⁺ | Major part in degradation [102] Fe-POM/CNNS- Nvac | PF | 2020 Self-assembly Visible light < 420 nm - | 18 min TCH | ATZ | ALA |MO | 4-CP | (~96.5%) | 4 Contributors h ⁺ | ¹O² |^·OH | ^·O²⁻ | [103] QDs-Fe/G | NRs-Fe/G | NSs-Fe/G | PF | 2015 GMSA Visible light pH (neutral) | 30 min Phenol | RhB | - Novel green synthesis | Scavenger - ^·OH [104] 3D FeO (OH)-rGA | PF | 2018 Facile method-Hummer’s Visible light pH (neutral) | 6 h 4-CP | 2,4,6-triCP | BPA | (80%) | 10 Activation of (^·OH) | π-π interaction [105] CQDs/α-FeOOH | PF |2020 Hydrolysis Visible light < 420 nm pH < 7 | 60 min TC (90%) | 5 Activation of (^·OH) | π → π* - transition [106] Fe₃O₄ (MPs)/(HA) Humic acid | pF | 2020 Co-precipitation Sunlight pH (<4) | 60 min CBZ | IBP |BPA| 5-TBA | 4-CP | Fe³⁺ → Fe²⁺ + e⁻ urban wastewater used [107] Fe₃O₄@void@TiO₂ | pF | 2017 Sol-gel UV light pH (3) | variable TC (100%) | 5 Fe³⁺ → Fe²⁺ + e⁻ [108] FeCu@Fe ²O3-g-C₃N₄ | pF | 2020 Calcination Visible light pH (3–11) | 6 h Aniline (80%) | 4 Degrading efficiency is high for FeCu-CN | [109] Fe₃O₄@MIL-100w | pF | 2015 Solvothermal Visible light pH (3–6.5) | 120 min MB (~99%) | 20 Activation of (^·OH) [110]

1.5 Photocatalysts as FMNs

      The potent essential energy provides vitamins for our present fast-moving lifestyles for easy and quick mobility together with prosperity [111]. Photocatalytic processes aid in conversion of the powerful solar energy to chemical and thus in degradation of unwanted variables [112–114]. Controllable target-oriented reactions of FMNs photocatalysis are productive, yielding positive segments. FMNs’ photocatalytic mechanistic reactions primarily depend upon the interactions between the light energy and the FMNs in question. The interfaces between the valence band (VB) and conduction band (CB) of a specific band energy initiate the utilization of photocatalytic activity for degrading the active toxins [115]. Generally, photocatalytic FMNs belong to a special group of semiconducting materials with a potency to destroy the organic/inorganic/biological pollutants present persistent in filthy water puddles [116, 117].

      Significantly, photocatalytic activity pertains to the absorption of photons by the semiconducting material that initiates the photogeneration of energetic negative (e⁻) electrons and positive (h⁺) holes between the CB and VB to begin a photo-redox reaction [118, 119]. The band energy gap is either same or more than that semiconducting material and often is on surface of these conducting materials, to generate highly active surface sites required for photocatalysis [120, 121]. A simple operative module is found to be effective for photocatalysis even in low concentration for semiconducting FNMs. Ample literatures are available for the synthesis of FNM PC and their versatile applications in remediation technologies, where the potency depends on methodologies adopted, morphological size, bandgap energy, effective dose, concentration of contaminant, temperature, and pH [122–124]. Reaction kinetics, parametric thermodynamics, and significant reaction mechanism provide a concrete base for further procedures [125, 126].

Authors Bagheri, S. et al. in their review suggested that one of the major setbacks while using UV light as source in heterogenous semiconductor with single carbon derivative as PC can be overcome by FNMs when employed for water treatment [127]. Photocatalytic activity of NMs is deprived due to reconfiguration of photoelectron. Loss of photoelectrons can be reduced by composites

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