Adsorption-enhanced catalytic oxidation for long-lasting dynamic degradation of organic dyes by porous manganese-based biopolymeric catalyst

Zheng, Jia Yu; He, Junda; Han, Chang Bao; Huang, Guoyu; Sun, Bei Chen; Zhao, Wen Kang; Wang, Yueshuai; Sun, Ling; Si, Junhui; Yan, Hui

doi:10.1016/j.ijbiomac.2023.124152

Cited by 7 publications

(4 citation statements)

References 70 publications

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“…Also, the EPR data showed that the manganese oxide–pomelo peels composite produces more reactive oxygen species, which leads to the strengthening of the oxidizing catalyst effect. XPS data also confirm the degradation of methylene blue to water and carbonate products [ 52 ].…”

Section: Organic Contaminatesmentioning

confidence: 88%

“…Adsorption Physio-sorption process [37] Ce-uio-66 MOF @Keratin composites Hydrogen bonding, π-π interaction, electrostatic interaction, and pore filling [40] Sodium alginate-bentonite clay (SA-B) nanocomposite hydrogels Exothermic adsorption and electrostatic interactions [46] Cuo-cellulose and chitosan (CS/CE) aerogel Exothermic, entropy-reduction, chemisorption, and single layer [50] Grafted gelatin/MMT nano clay nanocomposites Electrostatic forces and coordination bonding (metal ions of MMT nano clay) Hydrogen bonding interactions [67] Nanocomposite Zn 2+ @HAP@CS Electrostatic attraction (positively charged composite) [68] CS/PVA/rGO/graphene-based aerogels Capillary uptake and then chemical adsorption [101] DPEA-Cell-OSO −3 polymer Hydrogen bonding [104] Nanocomposites Alg/Gel/n-HAP/MNPs Hydrogen bonding Electrostatic interaction [28] Cs/PEG composite membrane [32] Composite biopolymer sponge GO-coated PS [35] Pop magnetic oak tannin gel (Fe 3 O 4 -OT) [75] Polyelectrolyte complexes CS-QSG Adsorption (heterogeneous multilayer) [31] Chitosan derived from mud crab (Scylla serrata) shells adsorbent Adsorption (monolayer and multilayer) [112] Enhancement in the absorption of visible light, robust electrostatic interactions, and charge separation of photogenerated charge carriers [111] Metal-oxide catalysts MnO x -PP Adsorption-enhanced catalytic oxidation [52]…”

Section: Starch-nife Ldh (S/nife-ldh) Compositementioning

confidence: 99%

“…Subsequently, through re-crosslinking, the biopolymer transforms into a porous material with a regulated pore size. Chitosan and pomelo peel are examples of biopolymers that have been processed into porous form using alkaline pretreatment [ 52 , 53 ].…”

Section: The Fabrication Of Porous Biopolymersmentioning

confidence: 99%

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Recent Advances in Porous Bio-Polymer Composites for the Remediation of Organic Pollutants

Tadayoni,

Dinari,

Roy

et al. 2024

Polymers

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The increasing awareness of the importance of a clean and sustainable environment, coupled with the rapid growth of both population and technology, has instilled in people a strong inclination to address the issue of wastewater treatment. This global concern has prompted individuals to prioritize the proper management and purification of wastewater. Organic pollutants are very persistent and due to their destructive effects, it is necessary to remove them from wastewater. In the last decade, porous organic polymers (POPs) have garnered interest among researchers due to their effectiveness in removing various types of pollutants. Porous biopolymers seem to be suitable candidates among POPs. Sustainable consumption and environmental protection, as well as reducing the consumption of toxic chemicals, are the advantages of using biopolymers in the preparation of effective composites to remove pollutants. Composites containing porous biopolymers, like other POPs, can remove various pollutants through absorption, membrane filtration, or oxidative and photocatalytic effects. Although composites based on porous biopolymers shown relatively good performance in removing pollutants, their insufficient strength limits their performance. On the other hand, in comparison with other POPs, including covalent organic frameworks, they have weaker performance. Therefore, porous organic biopolymers are generally used in composites with other compounds. Therefore, it seems necessary to research the performance of these composites and investigate the reasons for using composite components. This review exhaustively investigates the recent progress in the use of composites containing porous biopolymers in the removal of organic pollutants in the form of adsorbents, membranes, catalysts, etc. Information regarding the mechanism, composite functionality, and the reasons for using each component in the construction of composites are discussed. The following provides a vision of future opportunities for the preparation of porous composites from biopolymers.

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Section: Organic Contaminatesmentioning

confidence: 88%

Section: Starch-nife Ldh (S/nife-ldh) Compositementioning

confidence: 99%

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Recent Advances in Porous Bio-Polymer Composites for the Remediation of Organic Pollutants

Tadayoni,

Dinari,

Roy

et al. 2024

Polymers

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“…Based on the biopolymer pomelo peels (PP) and metal-oxide catalyst manganese oxide (MnOx), an adsorption-enhanced catalyst (MnOx-PP) was constructed for catalytic Methylene Blue oxidativedegradation [162]. The dye was adsorbed onto the biopolymer and then the continuous generation of active substances (O2 • and OH • ) degraded via an oxidative process the adsorbed dye molecules.…”

Section: Photocatalytic Degradation Of Methylene Blue Was Improved At...mentioning

confidence: 99%

Removal of Hazardous Organic Dyes from Liquid Wastes Using Advanced Nanomaterials

Alguacil,

Alonso

2024

Preprint

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The presence of organic dyes in aqueous environments is of extreme hazardousness against life due to the toxicity of these compounds. Thus, its removal from these various aquatic media is of the utmost importance and several technologies are constantly proven to match this goal. Among these technologies, various types of degradation and adsorption are the most widely used, and of the various types of materials used within these technologies, nanomaterials are constantly developed and investigated, probably due to the various properties that these nanomaterials presented. This work reviewed recent developments (2023 year) about the use of these nanomaterials on the treatment of solutions contaminated with these toxic organic dyes.

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Compressible polydopamine modified pomelo peel powder/poly(ethyleneimine)/κ-carrageenan aerogel with pH-tunable charge for selective removal of anionic and cationic dyes

Yu,

Tian,

Yao

et al. 2024

Carbohydrate Polymers

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Adsorption-enhanced catalytic oxidation for long-lasting dynamic degradation of organic dyes by porous manganese-based biopolymeric catalyst

Cited by 7 publications

References 70 publications

Recent Advances in Porous Bio-Polymer Composites for the Remediation of Organic Pollutants

Recent Advances in Porous Bio-Polymer Composites for the Remediation of Organic Pollutants

Removal of Hazardous Organic Dyes from Liquid Wastes Using Advanced Nanomaterials

Compressible polydopamine modified pomelo peel powder/poly(ethyleneimine)/κ-carrageenan aerogel with pH-tunable charge for selective removal of anionic and cationic dyes

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