Ag(I)-Hived Fullerene Microcube as an Enhanced Catalytic Substrate for the Reduction of 4-Nitrophenol and the Photodegradation of Orange G Dye

Liu, Renxuan; Hou, Ying; Jiang, Shangjun; Nie, Bei

doi:10.1021/acs.langmuir.0c00580

Cited by 14 publications

(8 citation statements)

References 38 publications

(54 reference statements)

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“…Due to their excellent advantages like complete mineralization of pollutants, no requirement for the disposal of sludge, and low energy consumption, several photocatalytic degradation techniques with dispersive nanostructured catalyst or substrate-supported nanostructured catalyst or catalyst-coated macroscale channel, or nanostructured catalyst-based microfluidic reactor have been put forward to carbonize relevant organic species in wastewater. Of all these photocatalytic degradation techniques, the nanostructured catalyst-based microfluidic reactor has been more often used thanks to its large surface-to-volume ratio, short diffusion distance and rapid mass transport process of molecules from an aqueous solution to catalysts, high illumination homogeneity, and accurate irradiation on nanostructured catalysts, no need of postseparation and recovery which are common for suspended catalysts, and 2 orders of magnitude higher photocatalytic efficiency. − The nanostructured catalysts mainly include metal oxide or sulfide semiconductors (that is, BiVO 4 , ZnO, , TiO 2 , , ZnS, and WO 3 ), noble metal-doped metal oxide semiconductors − (for instance, Ag/ZnO, Ga/ZnO, and Au/ZnO), and surface-sensitized metal oxide semiconductors (namely, C 60 /ZnO, Graphene/ZnO, and CuO/ZnO). Owing to the unique structure of the p-n heterojunction and the effectual inhibition of the combination of photogenerated electrons and holes, the nanostructured CuO/ZnONRs have excellent photodegradation performance and thus have been widely employed to construct various microfluidic reactors. − In regard to the evaluation of the photodegradation performance of these nanostructured catalyst-based microfluidic reactors, the experimental and numerical routes and eq have been invariably used in the literature, − where K A (min –1 ) is initial rate constant, K a (min –1 ) is kinetic adsorption rate constant, and K Lev (min –1 ) is mass transport-controlled constant.…”

Section: Introductionmentioning

confidence: 99%

Regulation of the Volume Flow Rate of Aqueous Methyl Blue Solution and the Wettability of CuO/ZnO Nanorods to Improve the Photodegradation Performance of Related Microfluidic Reactors

Jing

Gao

et al. 2021

Langmuir

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Six CuO/ZnO nanorod (CuO/ZnONR)-based microfluidic reactors were constructed for different UV irradiation durations, with which an aqueous methylene blue (MB) solution was photodegraded at varied volume flow rate Q. Via numerical and experimental routes, the effects of the Q on the kinetic adsorption rate constant K a and the initial rate constant K A of the CuO/ZnONR-based microfluidic reactors were discussed. Moreover, a reverse contacting angle (CA) trend of CuO/ZnONRs to the reaction constant K curve of corresponding CuO/ZnONR-based microfluidic reactor suggested that the CA of CuO/ZnONRs was another key influencing factor that affected greatly the photodegradation performance of the microfluidic reactors. The Q of the aqueous MB solution and the UV irradiation duration for the photodeposition of CuO/ZnONRs were optimized to be 125 μL/min and 1.0 h, the K of the CuO/ZnONR-based microfluidic reactors reached 4.84 min–1, and the related ΔK A/K was less than 6%. Similarly, these methods and results can be employed not only to enhance the mass transport and adsorption of specific species within other nanostructured matrix material-coated microchannels but also to enlarge the actual contacting surface areas between these microchannels and the related solution, which further improve the performance of other nanostructured catalyst-based microfluidic reactors, rGO microfluidic voltage generation, and a GOx/AuNW enzymatic glucose microfluidic sensor.

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Section: Introductionmentioning

confidence: 99%

Regulation of the Volume Flow Rate of Aqueous Methyl Blue Solution and the Wettability of CuO/ZnO Nanorods to Improve the Photodegradation Performance of Related Microfluidic Reactors

Jing

Gao

et al. 2021

Langmuir

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“…The rational explanation is the Ag + oxidization during exposure in atmosphere and under light radiation, especially for the Ag + ‐fullerene conjugated structure, which promotes the charge transfer and facilitate the oxidizing reaction. [ 23,24 ] Thus, the escalated oxygen peak, relative to a feeble nitrogen signal was observed in the resulting EDX spectrum. This is further verified by the following XPS survey (Figure S3), in which N atom also raises a rather weak EDX response, relative to its close neighbor, oxygen atom.…”

Section: Resultsmentioning

confidence: 99%

Direct transformation of AgNO₃ complex encapsulated Fullerene (C₆₀) microcrystal on solid silver Nitrate Crystal without organic Ligands

Hou

Pan

Dong

et al. 2020

Applied Organom Chemis

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We observed the unusual crystal transformation from solid AgNO3 to Ag(I)‐encapsulated fullerene (C60) microcrystal by a coordination‐driven crystallization, when casting C60 solution on AgNO3 crystal. The strong binding of Ag+‐C60 ruptures electrostatic interactions within AgNO3 lattice, forming a binary hybrid material, which was characterized by XRD, Raman spectroscopy and mass spectrometry. Our results support the fact that AgNO3 crystal can directly interact with fullerene C60 molecules, other than through solvated metal cations. Two major factors, namely sturdy Ag+‐olefin interaction and an enclosed cage effect play the dominating roles in crystal transformation. Adding to the regular solution‐based crystallization, this facial protocol is expected to render an additional dimension in fabrication of exohedral metallofullerene architecture, regardless of solubility of metal cation in anti‐solvent.

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“…Different nitroaromatics could be smoothly reduced with good to excellent yield using the present Cu/PBCR-600 catalyst, as shown in Table and Figure S10. 4-Nitrophenol, as a kind of toxic and hard-degradable organic compounds, − could be smoothly converted to 4-aminophenol with 98.5% yield over Cu/PBCR-600 (Table , entry 1). Figure S10a,b traces the reduction of 4-nitrophenol.…”

Section: Resultsmentioning

confidence: 99%

Cu-Based Catalysts Supported on H₃PO₄-Activated Coffee Biochar for Selective Reduction of Nitroaromatics

Gong,

Zhang,

et al. 2023

Langmuir

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Selective reduction of nitroaromatics to the corresponding aromatic amines is extremely an attractive chemical process for both fundamental research and potential commercial applications. Herewith, we report that a highly dispersed Cu catalyst supported on H3PO4-activated coffee biochar and the resulting Cu/PBCR-600 catalyst show complete conversion of the nitroaromatics and >97.0% selectivity for the corresponding aromatic amines. The TOF of catalyzing the reduction of nitroaromatics (1.55–460.74 min–1) is approximately 2 to 15 times higher than those of previously reported non-noble and even noble metal catalysts. Additionally, Cu/PBCR-600 also shows high stability in catalytic recycles. Furthermore, it exhibits long-term catalytic stability (660 min) for practical application in a continuous-flow reactor. The characterizations and activity tests reveal that Cu0 existing in Cu/PBCR-600 acts as an active site in nitroaromatics reduction. Also, the further characterization by FTIR and UV–vis demonstrates that N, P co-doped coffee biochar could selectively adsorb and activate the nitro group of nitroaromatics.

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Ag(I)-Hived Fullerene Microcube as an Enhanced Catalytic Substrate for the Reduction of 4-Nitrophenol and the Photodegradation of Orange G Dye

Cited by 14 publications

References 38 publications

Regulation of the Volume Flow Rate of Aqueous Methyl Blue Solution and the Wettability of CuO/ZnO Nanorods to Improve the Photodegradation Performance of Related Microfluidic Reactors

Regulation of the Volume Flow Rate of Aqueous Methyl Blue Solution and the Wettability of CuO/ZnO Nanorods to Improve the Photodegradation Performance of Related Microfluidic Reactors

Direct transformation of AgNO₃ complex encapsulated Fullerene (C₆₀) microcrystal on solid silver Nitrate Crystal without organic Ligands

Cu-Based Catalysts Supported on H₃PO₄-Activated Coffee Biochar for Selective Reduction of Nitroaromatics

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Ag(I)-Hived Fullerene Microcube as an Enhanced Catalytic Substrate for the Reduction of 4-Nitrophenol and the Photodegradation of Orange G Dye

Cited by 14 publications

References 38 publications

Regulation of the Volume Flow Rate of Aqueous Methyl Blue Solution and the Wettability of CuO/ZnO Nanorods to Improve the Photodegradation Performance of Related Microfluidic Reactors

Regulation of the Volume Flow Rate of Aqueous Methyl Blue Solution and the Wettability of CuO/ZnO Nanorods to Improve the Photodegradation Performance of Related Microfluidic Reactors

Direct transformation of AgNO3 complex encapsulated Fullerene (C60) microcrystal on solid silver Nitrate Crystal without organic Ligands

Cu-Based Catalysts Supported on H3PO4-Activated Coffee Biochar for Selective Reduction of Nitroaromatics

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Product

Resources

About

Direct transformation of AgNO₃ complex encapsulated Fullerene (C₆₀) microcrystal on solid silver Nitrate Crystal without organic Ligands

Cu-Based Catalysts Supported on H₃PO₄-Activated Coffee Biochar for Selective Reduction of Nitroaromatics