负载型新生态MnO<sub>2</sub>氧化BPA的效能与机制

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Abstract Mineral supported nascent MnO₂ (S-MnO₂) with porous structure was prepared via reducing KMnO₄ by plant poly-phenol (e.g., tannic acid) anchored on the surface of airstone. The oxidation performance and mechanism of endocrine disruptors (such as bisphenol A, BPA) over S-MnO₂ was investigated, and stability of S-MnO₂ in complicated water matrix was studied. Due to the porous net-work like structure, the recoverable S-MnO₂ exhibited good performance toward the oxidation of BPA. When the dosage of S-MnO₂ was 4.0g (containing 7.08μmol MnO₂), 94% of BPA was removed in 60min, which was 4.5 times higher than that over the same amount of powdery nascent MnO₂. Mechanism studies revealed that Mn(III) and Mn(IV) were both participated into the oxidation of BPA, and Mn(III) was essential to the rapid removal of BPA. The removal of BPA was mainly ascribed to the single electron transfer reaction, which enabled good resistance to complex surroundings like anions, cations and natural organic matters. S-MnO₂ was relative stable for BPA removal in consecutive runs and could be facile regenerated via the oxidation by KMnO₄, revealing a promising potential for further application.

Key words： supported nascent MnO₂ network-like structure Mn(III) bisphenol A

Received: 15 January 2024

PACS:

X703.5

Corresponding Authors: 王根,副教授,wanggen@xauat.edu.cn E-mail: wanggen@xauat.edu.cn

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	YIN Hao-chen
	QIN Xi-ran
	ZHANG Zhe-rui
	MA Ming-yu
	ZHAO Chun-ke
	LU Jin-suo
	WANG Gen

Cite this article:

YIN Hao-chen,QIN Xi-ran,ZHANG Zhe-rui等. Oxidation performance and mechanism of bisphenol A over supported nascent MnO₂[J]. CHINA ENVIRONMENTAL SCIENCECE, 2024, 44(8): 4610-4620.

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http://www.zghjkx.com.cn/EN/ OR http://www.zghjkx.com.cn/EN/Y2024/V44/I8/4610

[1] Bhadra B N, Jhung S H. A remarkable adsorbent for removal of contaminants of emerging concern from water: porous carbon derived from metal azolate framework-6[J]. Journal of Hazardous Materials, 2017,340:179-188.
[2] Dong Z Y, Lin Y L, Zhang T Y, et al. Enhanced degradation of emerging contaminants by permanganate/quinone process: Case study with bisphenol A [J]. Water Research, 2022,219:118528.
[3] Huang J, Zhong S, Dai Y, et al. Effect of MnO₂phase structure on the oxidative reactivity toward bisphenol A degradation [J]. Environmental Science & Technology, 2018,52(19):11309-11318.
[4] Yao J, Qu R, Wang X, et al. Visible light and fulvic acid assisted generation of Mn (III) to oxidize bisphenol A: The effect of tetrabromobisphenol A [J]. Water Research, 2020,169:115273.
[5] Yan X, Yi C, Wang Y, et al. Multi-catalysis of nano-zinc oxide for bisphenol A degradation in a dielectric barrier discharge plasma system: Effect and mechanism [J]. Separation and Purification Technology, 2020,231:115897.
[6] Ouyang D, Wu R, Xu Z, et al. Efficient degradation of Bisphenol A by Fe³⁺/Fe²⁺ cycle activating persulfate with the assistance of biochar- supported MoO₂ [J]. Chemical Engineering Journal, 2023,455:140381.
[7] Li L, Yang S, Wang Y, et al. Nitrogen-doped carbon nanosheets for efficient degradation of bisphenol A by H₂O₂ activation at neutral pH values [J]. Separation and Purification Technology, 2023,306:122687.
[8] Zhang Y, Wan Y, Zheng Y, et al. Potassium permanganate modification of hydrochar enhances sorption of Pb (II), Cu (II), and Cd (II) [J]. Bioresource Technology, 2023,386:129482.
[9] Zhang H, Shi Z, Bai R, et al. Role of TEMPO in enhancing permanganate oxidation toward organic contaminants [J]. Environmental Science & Technology, 2021,55(11):7681-7689.
[10] Wang S, Chen J, Sun Y, et al. Roles of MnO₂ colloids and Mn (III) during the oxidation of organic contaminants by permanganate [J]. Environmental Science & Technology, 2022,57(2):997-1005.
[11] Sun B, Zhang Y, Gong Z, et al. Reducing substances-enhanced degradation of pollutants by permanganate: the role of in situ formed colloidal MnO₂ [J]. Chemosphere, 2021,276:130203.
[12] Li G, Su Y, Wu B, et al. Initial formation and accumulation of manganese deposits in drinking water pipes: Investigating the role of microbial-mediated processes [J]. Environmental Science & Technology, 2022,56(9):5497-5507.
[13] Yang Y, Huang J, Wang S, et al. Catalytic removal of gaseous unintentional POPs on manganese oxide octahedral molecular sieves [J]. Applied Catalysis B: Environmental, 2013,142:568-578.
[14] Grebel J E, Charbonnet J A, Sedlak D L. Oxidation of organic contaminants by manganese oxide geomedia for passive urban stormwater treatment systems [J]. Water Research, 2016,88:481-491.
[15] Charbonnet J A, Duan Y, Van Genuchten C M, et al. Regenerated manganese-oxide coated sands: The role of mineral phase in organic contaminant reactivity [J]. Environmental Science & Technology, 2021,55(8):5282-5290.
[16] Wang Y, Zheng K, Guo H, et al. Potassium permanganate-based advanced oxidation processes for wastewater decontamination and sludge treatment: a review [J]. Chemical Engineering Journal, 2023, 452:139529.
[17] Zhu F, Guo Z, Hu X. Fluoride removal efficiencies and mechanism of schwertmannite from KMnO₄/MnO₂-Fe (II) processes [J]. Journal of Hazardous Materials, 2020,397:122789.
[18] Ge D, Yuan H, Xiao J, et al. Insight into the enhanced sludge dewaterability by tannic acid conditioning and pH regulation [J]. Science of the Total Environment, 2019,679:298-306.
[19] Che M, Wang X, Cui M, et al. Tannic acid enhanced the removal of Phaeocystis globosa from seawater by Fe (II) activated persulfate [J]. Journal of Environmental Chemical Engineering, 2023,11:111031.
[20] Chen C, Yang H, Yang X, et al. Tannic acid: A crosslinker leading to versatile functional polymeric networks: A review [J]. RSC Advances, 2022,12(13):7689-7711.
[21] Bigham A, Rahimkhoei V, Abasian P, et al. Advances in tannic acid-incorporated biomaterials: Infection treatment, regenerative medicine, cancer therapy, and biosensing [J]. Chemical Engineering Journal, 2022,432:134146.
[22] Cao H, Suib S L. Highly efficient heterogeneous photooxidation of 2-propanol to acetone with amorphous manganese oxide catalysts [J]. Journal of the American Chemical Society, 1994,116(12):5334-5342.
[23] Liu W, Sun B, Qiao J, et al. Influence of pyrophosphate on the generation of soluble Mn (III) from reactions involving Mn oxides and Mn (VII) [J]. Environmental Science & Technology, 2019,53(17): 10227-10235.
[24] Sun Y, Wang C, May A L, et al. Mn (III)-mediated bisphenol a degradation: Mechanisms and products [J]. Water Research, 2023,235:119787.
[25] Sun Y, Im J, Shobnam N, et al. Degradation of adsorbed bisphenol A by soluble Mn (III) [J]. Environmental Science & Technology, 2021, 55(19):13014-13023.
[26] Guo R, Qi Y, Li B, et al. Efficient degradation of alkyl imidazole ionic liquids in simulated sunlight irradiated periodate system: Kinetics, reaction mechanisms, and toxicity evolution [J]. Water Research, 2022, 226:119316.
[27] Qi H, Shi X, Liu Z, et al. In situ etched graphite felt modified with CuFe₂O₄/Cu₂O/Cu catalyst derived from CuFe PBA for the efficient removal of sulfamethoxazole through a heterogeneous electro-Fenton process [J]. Applied Catalysis B: Environmental, 2023,331:122722.
[28] Raj C J, Manikandan R, Sivakumar P, et al. Origin of capacitance decay for a flower-like δ-MnO₂ aqueous supercapacitor electrode: The quantitative surface and electrochemical analysis [J]. Journal of Alloys and Compounds, 2022,892:162199.
[29] 温子宁,谢春生,谢莹莹,等.锰氧化物负载施氏矿物去除酸性矿山废水中As(Ⅲ)的性能及机理[J]. 环境科学学报, 2021,41(12):4783- 4792. Wen Z N, Xie C S, Xie Y Y, et al. Removal performance and mechanism of As(III) by manganese oxide coated schwertmannite from acid mine drainage [J]. Acta Scientiae Circumstantiae, 2021, 41(12):4783-4792.
[30] Huang J, Dai Y, Singwald K, et al. Effects of MnO₂ of different structures on activation of peroxymonosulfate for bisphenol A degradation under acidic conditions [J]. Chemical Engineering Journal, 2019,370:906-915.
[31] Wang Z, Jia H, Zheng T, et al. Promoted catalytic transformation of polycyclic aromatic hydrocarbons by MnO₂ polymorphs: Synergistic effects of Mn³⁺ and oxygen vacancies [J]. Applied Catalysis B: Environmental, 2020,272:119030.
[32] Guo R, Xi B, Guo C, et al. Persulfate-based advanced oxidation processes: The new hope brought by nanocatalyst immobilization [J]. Environmental Functional Materials, 2022,1(1):67-91.
[33] Wang G, An W, Zhang Y, et al. Mesoporous carbon framework supported Cu-Fe oxides as efficient peroxymonosulfate catalyst for sustained water remediation [J]. Chemical Engineering Journal, 2022, 430:133060.
[34] Gao Y, Jiang J, Zhou Y, et al. Does soluble Mn (III) oxidant formed in situ account for enhanced transformation of triclosan by Mn (VII) in the presence of ligands? [J]. Environmental Science & Technology, 2018,52(8):4785-4793.
[35] Zhang Y, Wang F, Ou P, et al. High efficiency and rapid degradation of bisphenol A by the synergy between adsorption and oxidization on the MnO₂@ nano hollow carbon sphere [J]. Journal of Hazardous Materials, 2018,360:223-232.
[36] Deng Y H, Jeon J, Kim E M, et al. In situ immobilization of δ-MnO₂nanosheets on a porous support for rapid and continuous cleaning of bisphenol A-spiked water [J]. Chemical Engineering Journal, 2023,472:144653.
[37] Angaru G K R, Pal C A, Lingamdinne L P, et al. High-performance MnO₂ embedded fly ash zeolite applied for effective mineralization of bisphenol A and sorption of congo red: Mechanism, real water application, and toxicity assessment [J]. Chemical Engineering Science, 2024,286:119700.
[38] Yang S, Shobnam N, Sun Y, et al. The relative contributions of Mn (III) and Mn (IV) in manganese dioxide polymorphs to bisphenol A degradation [J]. Journal of Hazardous Materials, 2024,461:132596.
[39] Jia D, Hanna K, Mailhot G, et al. A review of Manganese (III)(Oxyhydr) Oxides use in advanced oxidation processes [J]. Molecules, 2021,26(19):5748.
[40] Cui J, Zhang L, Xi B, et al. Chemical oxidation of benzene and trichloroethylene by a combination of peroxymonosulfate and permanganate linked by in-situ generated colloidal/amorphous MnO₂ [J]. Chemical Engineering Journal, 2017,313:815-825.
[41] Mishra A, Goel D, Shankar S. Bisphenol A contamination in aquatic environments: A review of sources, environmental concerns, and microbial remediation [J]. Environmental Monitoring and Assessment, 2023,195(11):1352.
[42] Jin H, Zhu L. Occurrence and partitioning of bisphenol analogues in water and sediment from Liaohe River Basin and Taihu Lake, China [J]. Water Research, 2016,103:343-351.
[43] Sun B, Xiao Z, Dong H, et al. Bisulfite triggers fast oxidation of organic pollutants by colloidal MnO₂ [J]. Journal of Hazardous Materials, 2019,363:412-420.
[44] Zhao J, Liao R, Wang Q, et al. A new insight into the mechanism of carbamazepine oxidation by MnO₂: Crystalline structure versus Mn (III) [J]. Science of the Total Environment, 2021,753:141835.
[45] Wang J, Chai Z, Yang S, et al. Insights into the electron transfer regime of permanganate activation on carbon nanomaterial reduced from carbon dioxide [J]. Journal of Hazardous Materials, 2023,459:132094.
[46] Tan X, Wan Y, Huang Y, et al. Three-dimensional MnO₂ porous hollow microspheres for enhanced activity as ozonation catalysts in degradation of bisphenol A [J]. Journal of Hazardous Materials, 2017,321:162-172.
[47] 史胜利,冯佳,谢树莲,等.MnO₂-生物炭材料协同过一硫酸盐快速高效去除双酚A的行为和机理研究[J]. 环境科学学报, 2023, 43(2):73-86. Shi S L, Feng J, Xie S L, et al. Behavior and mechanism of MnO₂-biochar synergistic with PMS for rapid and efficient removal of bisphenol A [J]. Acta Scientiae Circumstantiae, 2023,43(2):73-86.
[48] Jia J, Liu D, Tian J, et al. Visible-light-excited humic acid for peroxymonosulfate activation to degrade bisphenol A [J]. Chemical Engineering Journal, 2020,400:125853.
[49] Li J Y, Liu Z Q, Cui Y H, et al. Abatement of aromatic contaminants from wastewater by a heat/persulfate process based on a polymerization mechanism [J]. Environmental Science & Technology, 2023,57(47):18575-18585.
[50] Yang Y, Ren W, Hu K, et al. Challenges in radical/nonradical-based advanced oxidation processes for carbon recycling [J]. Chem Catalysis, 2022,2(8):1858-1869.