Progress in the applications of metal-organic frameworks and derivatives activate persulfate in water treatment

doi:10.16085/j.issn.1000-6613.2019-0163

Abstract

Abstract:

Due to the metal ion-centered structural features, the metal-organic frameworks(MOFs) and their derivatives can be used to construct heterogeneous persulfate catalytic oxidation system. The heterogeneous persulfate activated process with low energy consumption and high efficiency has a good application prospect in water treatment. In this review, the activation of persulfate by MOFs and their derivatives to degrade refractory organic pollutants including organic dyes, environmental endocrine disruptors and antibiotics in aqueous solution were systematically presented. The effects of MOFs‘ and MOFs derivatives’ structure and composition on the catalytic degradation of organic pollutants were discussed. It was demonstrated that the rational structure design, synthesis strategy, unsaturated metal active sites of catalysts and active species in the catalytic oxidation system played a critical role in the degradation of organic pollutants. Finally, the problems existed in the MOFs-based heterogeneous persulfate activated system were summarized and it was proposed that the construction of a new high-efficiency combined activation system and the in-depth mechanism exploration and improvement would be the focus of future research.

Key words: metal-organic frameworks, persulfate, radical, catalysis, activation, water treatment, organic pollutants

摘要：

金属有机骨架材料（MOFs）具有以金属离子为中心的结构特征，因此利用MOFs及其衍生材料可构建非均相过硫酸盐催化氧化体系，该体系能耗低且高效，在水处理中具有良好的应用前景。本文综述了MOFs及其衍生材料活化过硫酸盐处理水中难降解有机污染物（包括有机染料、环境内分泌干扰物和抗生素）的研究现状，探讨了不同组成及结构的MOFs及MOFs衍生材料对催化降解水中有机污染物性能的影响，指出MOFs及其衍生材料的结构设计、合成策略、不饱和的金属活性位点以及反应体系中的活性物质等是体系催化降解能力的重要影响因素。最后总结了目前基于MOFs材料活化过硫酸盐作为一种新型的高级氧化技术在水处理应用研究中存在的问题，并提出新型高效联合活化体系的构建及活化作用机制深入的探索和完善是今后研究的重点。

关键词: 金属有机骨架材料, 过硫酸盐, 自由基, 催化, 活化, 水处理, 有机污染物

CLC Number:

TB383

Xiaojuan LI,Fengzhen LIAO,Lanmei YE,Zhenglin LIU. Progress in the applications of metal-organic frameworks and derivatives activate persulfate in water treatment[J]. Chemical Industry and Engineering Progress, 2019, 38(10): 4712-4721.

应用进展,李小娟,廖凤珍,叶兰妹,刘政霖. 金属有机骨架及其衍生材料活化过硫酸盐在水处理中的[J]. 化工进展, 2019, 38(10): 4712-4721.

References 33

1	蒲嘉懿 . 金属有机骨架材料衍生物活化过一硫酸氢钾降解水体中污染物[D]. 广州: 华南理工大学, 2017.
	PU J Y . Metal organic framework derivatives activate peroxymonosulfate to degrade pollutants in water[D]. Guangzhou: South China University of Technology, 2017.
2	LIANG C , HUANG C F , CHEN Y J . Potential for activated persulfate degradation of BTEX contamination[J]. Water Research, 2008, 42(15): 4091-4100.
3	周宁 . 超声/过硫酸盐法去除水中卡马西平及腐殖酸的研究[D]. 武汉: 华中科技大学, 2015.
	ZHOU N . Study on the degradation of carbamazepine and humic acid in water using ultrasonic combined with persulfate method[D]. Wuhan: Huazhong University of Science and Technology, 2015.
4	徐朋飞, 郭怡秦, 王光辉, 等 . 紫外活化过硫酸盐对甲基橙脱色处理实验研究[J]. 环境工程, 2017, 35(11): 58-60,80.
	XU P F , GUO Y Q , WANG G H , et al . Experrimental study on UV-activated persulfate for decolorization of methyl orange wastewater[J]. Environmental Engineering, 2017, 35(11): 58-60,80.
5	董紫君, 张茜, 代威力, 等 . 热活化过硫酸盐体系中碘离子的转化分析[J]. 中国给水排水, 2018, 34(15): 55-58,63.
	DONG Z J , ZHANG X , DAI W L , et al . Analysis on transformation of iodide in thermoactivated persulfate system[J]. China Water & Wastewater, 2018, 34(15): 55-58,63.
6	YAN J , LEI M , ZHU L , et al . Degradation of sulfamonomethoxine with Fe₃O₄ magnetic nanoparticles as heterogeneous activator of persulfate[J]. Journal of Hazardous Materials, 2011, 186(2/3): 1398-1404.
7	KAKAVANDI B . Heterogeneous Fenton-like catalytic oxidation of tetracycline by AC@Fe₃O₄ as a heterogeneous persulfate activator: adsorption and degradation studies[J]. Journal of Industrial & Engineering Chemistry, 2016, 45: 323-333.
8	MA Q , ZHANG X , GUO R , et al . Persulfate activation by magnetic -Fe₂O₃/Mn₃O₄ nanocomposites for degradation of organic pollutants[J]. Separation & Purification Technology, 2018, 210: 335-342.
9	CHEN L , ZUO X , YANG S , et al . Rational design and synthesis of hollow Co₃O₄@Fe₂O₃ core-shell nanostructure for the catalytic degradation of norfloxacin by coupling with peroxymonosulfate[J]. Chemical Engineering Journal, 2019, 359: 373-384.
10	RAMOS M A V , YAN W , LI X Q , et al . Simultaneous oxidation and reduction of arsenic by zero-valent iron nanoparticles: understanding the significance of the core-shell structure[J]. Journal of Physical Chemistry C, 2009, 113(33): 14591-14594.
11	BETTERTON E A , HOFFMANN M R . Kinetics and mechanism of the oxidation of aqueous hydrogen sulfide by peroxymonosulfate[J]. Environmental Science & Technology, 1990, 24(12): 1819-1824.
12	GÁBOR L , JÓZSEF K , ZSUZSA B , et al . One-versus two-electron oxidation with peroxomonosulfate ion: reactions with iron(Ⅱ), vanadium(Ⅳ), halide ions, and photoreaction with cerium(Ⅲ)[J]. Inorganic Chemistry, 2009, 48(4): 1763-1773.
13	丁耀彬 . 基于过渡金属氧化物催化活化过一硫酸盐高级氧化方法及其在有机污染物降解中的应用[D]. 武汉: 华中科技大学, 2013.
	DING Y B . Advanced oxidation technology based on activation of peroxymonosulfate by transition metal oxides for degradation of organic pollutants[D]. Wuhan: Huazhong University of Science and Technology, 2013.
14	SHARMA S B , MUDALIAR M , RAO B , et al . Radiation chemical oxidation of benzaldehyde, acetophenone, and benzophenone[J]. Journal of Physical Chemistry A, 1997, 101(45): 8402-8408.
15	FORSEY S . In situ chemical oxidation of creosote/coal tar residuals: experimental and numerical investigation[J]. Archives Roumaines de Pathologie Expérimentales et de Microbiologie, 2004, 28(2): 557-562.
16	LIANG C J , SU H . Identification of sulfate and hydroxyl radicals in thermally activated persulfate[J]. Industrial & Engineering Chemistry Research, 2009, 48(11): 472-475.
17	CLIFTON C L , HUIE R E . Rate constants for hydrogen abstraction reactions of the sulfate radical, SO₄ ^-· alcohols[J]. International Journal of Chemical Kinetics, 1989, 21(8): 677-687.
18	PADMAJA S , ALFASSI Z B , NETA P , et al . Rate constants for reactions of SO₄ ^-· radicals in acetonitrile[J]. International Journal of Chemical Kinetics, 1993, 25(3): 193-198.
19	HUANG K C , ZHAO Z , HOAG G E , et al . Degradation of volatile organic compounds with thermally activated persulfate oxidation[J]. Chemosphere, 2005, 61(4): 551-560.
20	HU L , DENG G , LU W , et al . Peroxymonosulfate activation by Mn₃O₄/metal-organic framework for degradation of refractory aqueous organic pollutant Rhodamine B[J]. Chinese Journal of Catalysis, 2017, 38(8): 1360-1372.
21	ZENG T , ZHANG X , WANG S , et al . Spatial confinement of a Co₃O₄ catalyst in hollow metal-organic frameworks as a nanoreactor for improved degradation of organic pollutants[J]. Environmental Science & Technology, 2015, 49(4): 2350-2357.
22	LIN K Y , CHANG H A . Zeolitic imidazole framework-67(ZIF-67) as a heterogeneous catalyst to activate peroxymonosulfate for degradation of Rhodamine B in water[J]. Journal of the Taiwan Institute of Chemical Engineers, 2015, 53: 40-45.
23	PU M , MA Y , WAN J , et al . Activation performance and mechanism of a novel heterogeneous persulfate catalyst: metal organic framework MIL-53(Fe) with Fe(Ⅱ)/Fe(Ⅲ) mixed-valence coordinative unsaturated iron center[J]. Catalysis Science & Technology, 2017, 7(5): 1129-1140.
24	PU M , GUAN Z , MA Y , et al . Synthesis of iron-based metal-organic framework MIL-53 as an efficient catalyst to activate persulfate for the degradation of orange G in aqueous solution[J]. Applied Catalysis A: General, 2018, 549: 82-92.
25	WANG M , YANG L , GUO C , et al . Bimetallic Fe/Ti-based metal-organic framework for persulfate-assisted visible light photocatalytic degradation of orange Ⅱ[J]. Chemistry Select, 2018, 3(13): 3664-3674.
26	LI H , WAN J , MA Y , et al . Degradation of refractory dibutyl phthalate by peroxymonosulfate activated with novel catalysts cobalt metal-organic frameworks: mechanism, performance, and stability[J]. Journal of Hazardous Materials, 2016, 318: 154-163.
27	YANG Q , CHOI H , ALABED S R , et al . Iron-cobalt mixed oxide nanocatalysts: heterogeneous peroxymonosulfate activation, cobalt leaching, and ferromagnetic properties for environmental applications[J]. Applied Catalysis B: Environmental, 2009, 88(3): 462-469.
28	BHATTACHARJEE S , CHOI J S , YANG S T , et al . Solvothermal synthesis of Fe-MOF-74 and its catalytic properties in phenol hydroxylation[J]. Journal of nanoscience and nanotechnology, 2010, 10(1): 135-141.
29	AI L , ZHANG C , LI L , et al . Iron terephthalate metal-organic framework: revealing the effective activation of hydrogen peroxide for the degradation of organic dye under visible light irradiation[J]. Applied Catalysis B: Environmental, 2014, 148/149: 191-200.
30	DU J J , YUAN Y P , SUN J X , et al . New photocatalysts based on MIL-53 metal–organic frameworks for the decolorization of methylene blue dye[J]. Journal of Hazardous Materials, 2011, 190(1): 945-951.
31	MEI W , LI D , XU H , et al . Effect of electronic migration of MIL-53(Fe) on the activation of peroxymonosulfate under visible light[J]. Chemical Physics Letters, 2018, 706: 694-701.
32	GAO Y , LI S , LI Y , et al . Accelerated photocatalytic degradation of organic pollutant over metal-organic framework MIL-53(Fe) under visible LED light mediated by persulfate[J]. Applied Catalysis B: Environmental, 2017, 202: 165-174.
33	LIN K Y , CHANG H A , HSU C J . Iron-based metal organic framework, MIL-88A, as a heterogeneous persulfate catalyst for decolorization of Rhodamine B in water[J]. RSC Advances, 2015, 5(41): 32520-32530.

[1]	YANG Xiazhen, PENG Yifan, LIU Huazhang, HUO Chao. Regulation of active phase of fused iron catalyst and its catalytic performance of Fischer-Tropsch synthesis [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 310-318.
[2]	ZHENG Qian, GUAN Xiushuai, JIN Shanbiao, ZHANG Changming, ZHANG Xiaochao. Photothermal catalysis synthesis of DMC from CO₂ and methanol over Ce_0.25Zr_0.75O₂ solid solution [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 319-327.
[3]	WANG Zhengkun, LI Sifang. Green synthesis of gemini surfactant decyne diol [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 400-410.
[4]	WANG Ying, HAN Yunping, LI Lin, LI Yanbo, LI Huili, YAN Changren, LI Caixia. Research status and future prospects of the emission characteristics of virus aerosols in urban wastewater treatment plants [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 439-446.
[5]	DENG Liping, SHI Haoyu, LIU Xiaolong, CHEN Yaoji, YAN Jingying. Non-noble metal modified vanadium titanium-based catalyst for NH₃-SCR denitrification simultaneous control VOCs [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 542-548.
[6]	GENG Yuanze, ZHOU Junhu, ZHANG Tianyou, ZHU Xiaoyu, YANG Weijuan. Homogeneous/heterogeneous coupled combustion of heptane in a partially packed bed burner [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4514-4521.
[7]	CHENG Tao, CUI Ruili, SONG Junnan, ZHANG Tianqi, ZHANG Yunhe, LIANG Shijie, PU Shi. Analysis of impurity deposition and pressure drop increase mechanisms in residue hydrotreating unit [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4616-4627.
[8]	WANG Jingang, ZHANG Jianbo, TANG Xuejiao, LIU Jinpeng, JU Meiting. Research progress on modification of Cu-SSZ-13 catalyst for denitration of automobile exhaust gas [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4636-4648.
[9]	GAO Yanjing. Analysis of international research trend of single-atom catalysis technology [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4667-4676.
[10]	GE Quanqian, XU Mai, LIANG Xian, WANG Fengwu. Research progress on the application of MOFs in photoelectrocatalysis [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4692-4705.
[11]	LI Dongze, ZHANG Xiang, TIAN Jian, HU Pan, YAO Jie, ZHU Lin, BU Changsheng, WANG Xinye. Research progress of NO _x reduction by carbonaceous substances for denitration in cement kiln [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4882-4893.
[12]	WANG Chen, BAI Haoliang, KANG Xue. Performance study of high power UV-LED heat dissipation and nano-TiO₂ photocatalytic acid red 26 coupling system [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4905-4916.
[13]	BAI Zhihua, ZHANG Jun. Oxidative removal of NO in DTPMPA/Fenton system [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4967-4973.
[14]	PAN Yichang, ZHOU Rongfei, XING Weihong. Advanced microporous membranes for efficient separation of same-carbon-number hydrocarbon mixtures: State-of-the-art and challenges [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 3926-3942.
[15]	WU Haibo, WANG Xilun, FANG Yanxiong, JI Hongbing. Progress of the development and application of 3D printing catalyst [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 3956-3964.