Adsorption Behaviors and Mechanism of Phenol and Catechol in Wastewater by Magnetic Graphene Oxides: A Comprehensive Study Based on Adsorption Experiments, Mathematical Models, and Molecular Simulations

Wu, Yuhua; Zhang, Xi; Liu, Caizhu; Tian, Lina; Zhang, Yufan; Zhu, Meilin; Qiao, Weiye; Wu, Jianbo; Yan, Shu; Zhang, Hui; Bai, Hongcun

doi:10.1021/acsomega.3c09346

ACS Omega

2024

DOI: 10.1021/acsomega.3c09346

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Adsorption Behaviors and Mechanism of Phenol and Catechol in Wastewater by Magnetic Graphene Oxides: A Comprehensive Study Based on Adsorption Experiments, Mathematical Models, and Molecular Simulations

Yuhua Wu,

Xi Zhang,

Caizhu Liu

et al.

Abstract: This study provides a comprehensive analysis of the adsorption behaviors and mechanisms of phenol and catechol on magnetic graphene oxide (MGO) nanocomposites based on adsorption experiments, mathematical models, and molecular simulations. Through systematic experiments, the influence of various parameters, including contact time, pH conditions, and ionic strength, on the adsorption efficacy was comprehensively evaluated. The optimal contact time for adsorption was identified as 60 min, with the observation th… Show more

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Cited by 2 publications

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MXene-Derived Nano N-TiO₂@MXene Loaded with Fe₃O₄ for Photo-Fenton Synergistic Degradation of Phenol

Hu,

Zhang,

Zhong

et al. 2024

ACS Appl. Nano Mater.

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Phenol is a volatile organic compound, and conventional treatment processes prove to be ineffective for its degradation. The designable electron transfer structures of Fenton-based catalysts show great potential for wastewater treatment. However, attaining a balance between recycling and degradation efficiency remains a challenge. Herein, we prepared a photocatalyst with improved visible-light excitation characteristics. Magnetic N-TiO2/Fe3O4@MXene was prepared by loading N-TiO2 nanoparticles and Fe3O4 onto multilayered MXenes. N-TiO2/Fe3O4@MXene exhibited stable magnetic characteristics (27.1 emu/g) and a high degradation capacity for phenol. The catalyst also showed better performance for phenol removal under simulated solar-light (200–800 nm) irradiation compared with those of other catalysts. The phenol removal rate of the catalyst in the concentration range of 20–60 ppm reached 98% after 30 min of solar-light irradiation. The degradation curves of phenol were kinetically fitted. After four cycles of testing, the material maintained a high efficiency for the degradation of phenol. A total organic carbon removal rate of 61% was achieved in 10 min. The intermediates of phenol degradation were determined via liquid chromatography–mass spectrometry to gain insights into the degradation pathways of phenol. This study paves the way for the development of efficient photo-Fenton-based catalytic systems with good magnetic separation capabilities, which can promote their application in wastewater treatment.

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MXene-Derived Nano N-TiO₂@MXene Loaded with Fe₃O₄ for Photo-Fenton Synergistic Degradation of Phenol

Hu,

Zhang,

Zhong

et al. 2024

ACS Appl. Nano Mater.

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An Insight into the Molecular Electronic Structure of Graphene Oxides and Their Interactions with Molecules of Different Polarities Using Quantum Chemical and COSMO-RS Calculations

Ferro,

Merino,

Lopez

et al. 2024

Molecules

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A systematic theoretical study on the molecular electronic structure of graphene and its oxides, including their interactions with molecular species of different polarity, was carried out. The influence of the O/C atomic ratio in the graphene oxides was also evaluated. Quantum chemical and COSMO-based statistical-thermodynamic calculations were performed. Geometry optimizations demonstrated that graphene sheets are structurally distorted by oxygen substitution, although they show high resistance to deformation. Furthermore, under axial O-C bonding, proton-donor and proton-acceptor centers are created on the graphene oxide surface, which could acquire an amphoteric character. In low-oxidized graphene oxides, H-bonding centers coexist with neutral highly polarizable π electron clouds. Deep graphene oxidation is also related to the formation of a quasi-two-dimensional H-bond network. These two phenomena are responsible for the exceptional adsorption and catalytic properties and the potential proton conductivity of graphene oxides. The current calculations demonstrated that the interactions of polar molecular species with deep-oxidized graphene derivatives are thermodynamically favorable, but not with low-oxidized ones. The capacity of the quantum chemical and COSMO-RS calculations to model all these issues opens the possibility of selecting or designing graphene-based materials with optimized properties for specific applications. Also, they are valuable in selecting/designing solvents with good exfoliant properties with respect to certain graphene derivatives.

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Adsorption Behaviors and Mechanism of Phenol and Catechol in Wastewater by Magnetic Graphene Oxides: A Comprehensive Study Based on Adsorption Experiments, Mathematical Models, and Molecular Simulations

Cited by 2 publications

References 60 publications

MXene-Derived Nano N-TiO₂@MXene Loaded with Fe₃O₄ for Photo-Fenton Synergistic Degradation of Phenol

MXene-Derived Nano N-TiO₂@MXene Loaded with Fe₃O₄ for Photo-Fenton Synergistic Degradation of Phenol

An Insight into the Molecular Electronic Structure of Graphene Oxides and Their Interactions with Molecules of Different Polarities Using Quantum Chemical and COSMO-RS Calculations

Contact Info

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Resources

About

Adsorption Behaviors and Mechanism of Phenol and Catechol in Wastewater by Magnetic Graphene Oxides: A Comprehensive Study Based on Adsorption Experiments, Mathematical Models, and Molecular Simulations

Cited by 2 publications

References 60 publications

MXene-Derived Nano N-TiO2@MXene Loaded with Fe3O4 for Photo-Fenton Synergistic Degradation of Phenol

MXene-Derived Nano N-TiO2@MXene Loaded with Fe3O4 for Photo-Fenton Synergistic Degradation of Phenol

An Insight into the Molecular Electronic Structure of Graphene Oxides and Their Interactions with Molecules of Different Polarities Using Quantum Chemical and COSMO-RS Calculations

Contact Info

Product

Resources

About

MXene-Derived Nano N-TiO₂@MXene Loaded with Fe₃O₄ for Photo-Fenton Synergistic Degradation of Phenol

MXene-Derived Nano N-TiO₂@MXene Loaded with Fe₃O₄ for Photo-Fenton Synergistic Degradation of Phenol