Sulfite activation technology and its application in wastewater treatment

doi:10.16085/j.issn.1000-6613.2021-0340

Abstract

Abstract:

As a by-product of desulfurization, sulfite has the advantages of low price, low toxicity and simple preparation. It can be activated to produce sulfate radicals (SO $4 · -$ ), sulfite free radicals (SO $3 · -$ ), peroxysulfate radicals (SO $5 · -$ ), hydroxyl radicals (OH^?) and many other active substances with high oxidation potential to oxidize and degrade various organic pollutants quickly and efficiently. Therefore, sulfite is regarded as a more economical and environmentally friendly alternative to persulfate. This article reviews the research progress of sulfite activation technology, including transition metal ion activation, ultraviolet light radiation activation and oxygen-containing metal acid salt activation, etc.. The mechanism of sulfite activation such as the radical chain reaction of transition metal activated sulfite and the formation of free radicals by ultraviolet radiation sulfite photolysis is introduced in detail. The research status of sulfite advanced oxidation process for the treatment of various organic wastewater is summarized. At present, this technology has significant effects in the treatment of a variety of refractory wastewater, but most of the research is still at the experimental stage and the treatment object is single. There is little research on actual wastewater treatment.

Key words: sulfite, transition metal, activation, radical, oxidation, wastewater

摘要：

亚硫酸盐作为一种脱硫副产物，具有价格低廉、毒性低、制备简便等优点，可被活化产生硫酸根自由基（ $S O 4 · -$ ）、亚硫酸根自由基（ $S O 3 · -$ ）、过氧硫酸根自由基（ $S O 5 · -$ ）和羟基自由基（OH^?）等多种氧化电位高的活性物质，能够快速高效地氧化降解各种有机污染物。因此，亚硫酸盐被视为更经济环保的过硫酸盐替代品。本文综述了亚硫酸盐活化技术的研究进展，包括过渡金属离子活化、紫外光辐射活化和含氧金属酸盐活化等；详细介绍了过渡金属活化亚硫酸盐发生自由基链式反应和紫外辐射亚硫酸盐光解生成自由基等亚硫酸盐活化机理；并归纳总结了亚硫酸盐高级氧化法处理各类有机废水的研究现状。目前，该技术在处理多种难降解废水方面有着显著的效果，但大多数研究仍停留在实验阶段，且处理对象单一，在实际废水处理方面研究尚少。

关键词: 亚硫酸盐, 过渡金属, 活化, 自由基, 氧化, 废水

CLC Number:

X523

JIA Yanping, XUE Dongqi, LIU Qifan, ZHANG Haifeng, LI Zheng, ZHANG Lanhe. Sulfite activation technology and its application in wastewater treatment[J]. Chemical Industry and Engineering Progress, 2022, 41(1): 418-426.

贾艳萍, 薛东奇, 刘启帆, 张海丰, 李正, 张兰河. 亚硫酸盐活化技术及其在废水处理中的应用[J]. 化工进展, 2022, 41(1): 418-426.

Figures/Tables 6

References 46

1	MATTA R, TLILI S, CHIRON S, et al. Removal of carbamazepine from urban wastewater by sulfate radical oxidation[J]. Environmental Chemistry Letters, 2011, 9(3): 347-353.
2	BUXTON G V, GREENSTOCK C L, HELMAN W P, et al. Critical review of rate constants for reactions of hydrated electrons, hydrogen atoms and hydroxyl radicals (·OH/·O^-) in aqueous solution[J]. Journal of Physical and Chemical Reference Data, 1988, 17(2): 513-886.
3	PIKAEV A K, ZOLOTAREVSKII V I. Pulse radiolysis of aqueous solutions of sulfuric acid[J]. Bulletin of the Academy of Sciences of the USSR, Division of Chemical Science, 1967, 16(1): 181-182.
4	HUANG Y, HAN C S, LIU Y Q, et al. Degradation of atrazine by Zn_xCu_1-_xFe₂O₄ nanomaterial-catalyzed sulfite under UV-vis light irradiation: green strategy to generate SO4·-[J]. Applied Catalysis B: Environmental, 2018, 221: 380-392.
5	CHEN L, PENG X Z, LIU J H, et al. Decolorization of Orange Ⅱ in aqueous solution by an Fe(Ⅱ)/sulfite system: replacement of persulfate[J]. Industrial & Engineering Chemistry Research, 2012, 51(42): 13632-13638.
6	YUAN Y N, LUO T, XU J, et al. Enhanced oxidation of aniline using Fe(Ⅲ)-S(Ⅳ) system: role of different oxysulfur radicals[J]. Chemical Engineering Journal, 2019, 362: 183-189.
7	ZUO Y G, ZHAN J. Effects of oxalate on Fe-catalyzed photooxidation of dissolved sulfur dioxide in atmospheric water[J]. Atmospheric Environment, 2005, 39(1): 27-37.
8	CONKLIN M H, HOFFMANN M R. Metal ion-sulfur(Ⅳ) chemistry. 2. Kinetic studies of the redox chemistry of copper(Ⅱ)-sulfur(Ⅳ) complexes[J]. Environmental Science & Technology, 1988, 22(8): 891-898.
9	ZHOU D N, CHEN L, LI J J, et al. Transition metal catalyzed sulfite auto-oxidation systems for oxidative decontamination in waters: a state-of-the-art minireview[J]. Chemical Engineering Journal, 2018, 346: 726-738.
10	KOTRONAROU A, SIGG L. Sulfur dioxide oxidation in atmospheric water: role of iron(Ⅱ) and effect of ligands[J]. Environmental Science & Technology, 1993, 27(13): 2725-2735.
11	XIE P C, GUO Y Z, CHEN Y Q, et al. Application of a novel advanced oxidation process using sulfite and zero-valent iron in treatment of organic pollutants[J]. Chemical Engineering Journal, 2017, 314: 240-248.
12	LIU Z Z, GUO Y Z, SHANG R, et al. A triple system of Fe(Ⅲ)/sulfite/persulfate: decolorization and mineralization of reactive Brilliant Red X-3B in aqueous solution at near-neutral pH values[J]. Journal of the Taiwan Institute of Chemical Engineers, 2016, 68: 162-168.
13	BRANDT C, FABIAN I, ELDIK R VAN. Kinetics and mechanism of the iron(Ⅲ)-catalyzed autoxidation of sulfur(Ⅳ) oxides in aqueous solution. Evidence for the redox cycling of iron in the presence of oxygen and modeling of the overall reaction mechanism[J]. Inorganic Chemistry, 1994, 33(4): 687-701.
14	ANIPSITAKIS G P, DIONYSIOU D D. Degradation of organic contaminants in water with sulfate radicals generated by the conjunction of peroxymonosulfate with cobalt[J]. Environmental Science & Technology, 2003, 37(20): 4790-4797.
15	YUAN Y N, ZHAO D, LI J J, et al. Rapid oxidation of paracetamol by Cobalt(Ⅱ) catalyzed sulfite at alkaline pH[J]. Catalysis Today, 2018, 313: 155-160.
16	LIU Z Z, YANG S J, YUAN Y N, et al. A novel heterogeneous system for sulfate radical generation through sulfite activation on a CoFe₂O₄ nanocatalyst surface[J]. Journal of Hazardous Materials, 2017, 324: 583-592.
17	BERGLUND J, FRONAEUS S, ELDING L I. Kinetics and mechanism for manganese-catalyzed oxidation of sulfur(Ⅳ) by oxygen in aqueous solution[J]. Inorganic Chemistry, 1993, 32(21): 4527-4538.
18	FISCHER M, WARNECK P. Photodecomposition and photooxidation of hydrogen sulfite in aqueous solution[J]. The Journal of Physical Chemistry, 1996, 100(37): 15111-15117.
19	YERMAKOV A N, ZHITOMIRSKY B M, POSKREBYSHEV G A, et al. Kinetic study of SO₅^- and HO₂ radicals reactivity in aqueous phase bisulfite oxidation[J]. The Journal of Physical Chemistry A, 1995, 99(10): 3120-3127.
20	XIAO Q, WANG T, YU S L, et al. Influence of UV lamp, sulfur(Ⅳ) concentration, and pH on bromate degradation in UV/sulfite systems: mechanisms and applications[J]. Water Research, 2017, 111: 288-296.
21	FENG M B, SHARMA V K. Enhanced oxidation of antibiotics by ferrate(Ⅵ)-sulfur(Ⅳ) system: elucidating multi-oxidant mechanism[J]. Chemical Engineering Journal, 2018, 341: 137-145.
22	SUN S F, PANG S Y, JIANG J, et al. The combination of ferrate(Ⅵ) and sulfite as a novel advanced oxidation process for enhanced degradation of organic contaminants[J]. Chemical Engineering Journal, 2018, 333: 11-19.
23	ZHANG J, ZHU L, SHI Z Y, et al. Rapid removal of organic pollutants by activation sulfite with ferrate[J]. Chemosphere, 2017, 186: 576-579.
24	WALDEMER R H, TRATNYEK P G. Kinetics of contaminant degradation by permanganate[J]. Environmental Science & Technology, 2006, 40(3): 1055-1061.
25	SUN B, GUAN X H, FANG J Y, et al. Activation of manganese oxidants with bisulfite for enhanced oxidation of organic contaminants: the involvement of Mn(Ⅲ)[J]. Environmental Science & Technology, 2015, 49(20): 12414-12421.
26	SUN B, LI D, LINGHU W S, et al. Degradation of ciprofloxacin by manganese(Ⅲ) intermediate: insight into the potential application of permanganate/bisulfite process[J]. Chemical Engineering Journal, 2018, 339: 144-152.
27	YU Y T, LI S Q, PENG X Z, et al. Efficient oxidation of Bisphenol A with oxysulfur radicals generated by iron-catalyzed autoxidation of sulfite at circumneutral pH under UV irradiation[J]. Environmental Chemistry Letters, 2016, 14(4): 527-532.
28	XIE P C, MA J, LIU W, et al. Removal of 2-MIB and geosmin using UV/persulfate: contributions of hydroxyl and sulfate radicals[J]. Water Research, 2015, 69: 223-233.
29	NETA P, HUIE R E, ROSS A B. Rate constants for reactions of inorganic radicals in aqueous solution[J]. Journal of Physical and Chemical Reference Data, 1988, 17(3): 1027-1284.
30	XIE P C, ZHANG L, CHEN J H, et al. Enhanced degradation of organic contaminants by zero-valent iron/sulfite process under simulated sunlight irradiation[J]. Water Research, 2019, 149: 169-178.
31	GUO Y G, LOU X Y, FANG C L, et al. Novel photo-sulfite system: toward simultaneous transformations of inorganic and organic pollutants[J]. Environmental Science & Technology, 2013, 47(19): 11174-11181.
32	ZHANG L, CHEN L, XIAO M, et al. Enhanced decolorization of Orange Ⅱ solutions by the Fe(Ⅱ)-sulfite system under xenon lamp irradiation[J]. Industrial & Engineering Chemistry Research, 2013, 52(30): 10089-10094.
33	ZHOU D N, CHEN L, ZHANG C B, et al. A novel photochemical system of ferrous sulfite complex: kinetics and mechanisms of rapid decolorization of Acid Orange 7 in aqueous solutions[J]. Water Research, 2014, 57: 87-95.
34	LI X C, MA J, LIU G F, et al. Efficient reductive dechlorination of monochloroacetic acid by sulfite/UV process[J]. Environmental Science & Technology, 2012, 46(13): 7342-7349.
35	DU J S, GUO W Q, WANG H Z, et al. Hydroxyl radical dominated degradation of aquatic sulfamethoxazole by Fe⁰/bisulfite/O₂: kinetics, mechanisms, and pathways[J]. Water Research, 2018, 138: 323-332.
36	PASIUK-BRONIKOWSKA W, BRONIKOWSKI T, ULEJCZYK M. Mechanism and kinetics of autoxidation of calcium sulfite slurries[J]. Environmental Science & Technology, 1992, 26(10): 1976-1981.
37	ZHANG J M, MA J, SONG H R, et al. Organic contaminants degradation from the S(Ⅳ) autoxidation process catalyzed by ferrous-manganous ions: a noticeable Mn(Ⅲ) oxidation process[J]. Water Research, 2018, 133: 227-235.
38	RAO D D, SUN Y K, SHAO B B, et al. Activation of oxygen with sulfite for enhanced removal of Mn(‍Ⅱ): the involvement of SO4·-[J]. Water Research, 2019, 157: 435-444.
39	BRANDT C, ELDIK R VAN. Transition metal-catalyzed oxidation of sulfur(Ⅳ) oxides. Atmospheric-relevant processes and mechanisms[J]. Chemical Reviews, 1995, 95(1): 119-190.
40	ENTEZARI M, GODINI H, SHEIKHMOHAMMADI A, et al. Enhanced degradation of polychlorinated biphenyls with simultaneous usage of reductive and oxidative agents over UV/sulfite/TiO₂ process as a new approach of advanced oxidation/reduction processes[J]. Journal of Water Process Engineering, 2019, 32: 100983.
41	XIE B H, LI X C, HUANG X F, et al. Enhanced debromination of 4-bromophenol by the UV/sulfite process: efficiency and mechanism[J]. Journal of Environmental Sciences, 2017, 54: 231-238.
42	YU K E, LI X C, CHEN L W, et al. Mechanism and efficiency of contaminant reduction by hydrated electron in the sulfite/iodide/UV process[J]. Water Research, 2018, 129: 357-364.
43	袁光明, 皮若冰, 吴钊成, 等. 高铁酸盐-亚硫酸盐体系氧化降解水中污染物阿特拉津[J]. 化工进展, 2020, 39(9): 3794-3800.
	YUAN Guangming, PI Ruobing, WU Zhaocheng, et al. Oxidative degradation of atrazine in water by ferrate-sulfite system[J]. Chemical Industry and Engineering Progress, 2020, 39(9): 3794-3800.
44	ACOSTA-RANGEL A, SÁNCHEZ-POLO M, ROZALEN M, et al. Comparative study of the oxidative degradation of different 4-aminobenzene sulfonamides in aqueous solution by sulfite activation in the presence of Fe(0), Fe(Ⅱ), Fe(Ⅲ) or Fe(Ⅵ)[J]. Water, 2019, 11(11): 2332.
45	ZHONG S F, ZHANG H C. New insight into the reactivity of Mn(Ⅲ) in bisulfite/permanganate for organic compounds oxidation: the catalytic role of bisulfite and oxygen[J]. Water Research, 2019, 148: 198-207.
46	SHI Z Y, JIN C, ZHANG J, et al. Insight into mechanism of arsanilic acid degradation in permanganate-sulfite system: role of reactive species[J]. Chemical Engineering Journal, 2019, 359: 1463-1471.

[1]	WANG Fu'an. Consumption and emission reduction of the reactor of 300kt/a propylene oxide process [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 213-218.
[2]	ZHANG Mingyan, LIU Yan, ZHANG Xueting, LIU Yake, LI Congju, ZHANG Xiuling. Research progress of non-noble metal bifunctional catalysts in zinc-air batteries [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 276-286.
[3]	GAO Yufei, LU Jinfeng. Mechanism of heterogeneous catalytic ozone oxidation:A review [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 430-438.
[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]	GU Yongzheng, ZHANG Yongsheng. Dynamic behavior and kinetic model of Hg⁰ adsorption by HBr-modified fly ash [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 498-509.
[6]	ZHAO Jingchao, TAN Ming. Effect of surfactants on the reduction of industrial saline wastewater by electrodialysis [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 529-535.
[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]	WANG Weitao, BAO Tingyu, JIANG Xulu, HE Zhenhong, WANG Kuan, YANG Yang, LIU Zhaotie. Oxidation of benzene to phenol over aldehyde-ketone resin based metal-free catalyst [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4706-4715.
[10]	GE Yafen, SUN Yu, XIAO Peng, LIU Qi, LIU Bo, SUN Chengying, GONG Yanjun. Research progress of zeolite for VOCs removal [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4716-4730.
[11]	LEI Wei, JIANG Weijia, WANG Yugao, HE Minghao, SHEN Jun. Synthesis of N,S co-doped coal-based carbon quantum dots by electrochemical oxidation and its application in Fe³⁺ detection [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4799-4807.
[12]	BAI Zhihua, ZHANG Jun. Oxidative removal of NO in DTPMPA/Fenton system [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4967-4973.
[13]	WANG Qi, KOU Lihong, WANG Guanyu, WANG Jikun, LIU Min, LI Lanting, WANG Hao. Molecular recognition of dissolved organic matter in bio-treated effluent of coking wastewater [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4984-4993.
[14]	SHI Tianxi, SHI Yonghui, WU Xinying, ZHANG Yihao, QIN Zhe, ZHAO Chunxia, LU Da. Effects of Fe²⁺ on the performance of Anammox EGSB reactor [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 5003-5010.
[15]	LYU Chengyuan, ZHANG Han, YANG Mingwang, DU Jianjun, FAN Jiangli. Recent advances of dioxetane-based afterglow system for bio-imaging [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4108-4122.