活性炭纤维负载硫化纳米零价铁用于活化PMS降解三氯苯酚

张子薇; 王李新; 甄建政; 唐念念; 李豪; 孙佳豪; 靳浠洋; 吕维扬

doi:10.12030/j.cjee.202307008

活性炭纤维负载硫化纳米零价铁用于活化PMS降解三氯苯酚

1.
浙江理工大学材料科学与工程学院，纺织纤维材料与加工技术国家地方联合工程实验室，杭州 310018
2.
浙江省现代纺织技术创新中心，绍兴 312000

作者简介: 张子薇 (1999—) ，女，硕士研究生，202130302215@mails.zstu.edu.cn

通讯作者: 吕维扬(1991—)，男，博士，副研究员，wylv@zstu.edu.cn

基金项目:
国家自然科学基金青年资助项目(52003240)；浙江省自然科学基金资助项目(Lq21B070007)；中国博士后科学基金资助项目(2022M722818)
中图分类号: X703

Degradation of trichlorophenol by activated carbon fibers-supported S-nZVI activating PMS

1.
National Engineering Laboratory for Textile Fiber Materials & Processing Technology, Zhejiang Sci-Tech University Hangzhou 310018, China
2.
Zhejiang Provincial Innovation Center of Advanced Textile Technology, Shaoxing 312000, China

Corresponding author: LYU Weiyang, wylv@zstu.edu.cn

摘要: 针对纳米零价铁(nanoscale zero-valent iron，nZVI)在反应过程中易团聚、易钝化和难回收等问题，采用比表面积大、化学稳定性好的活性炭纤维(activated carbon fibers，ACFs)作为载体，以连二亚硫酸钠(Na₂S₂O₄)作为硫化试剂，制备活性炭纤维负载硫化纳米零价铁复合材料(activated carbon fibers supported sulfidized nanoscale zero-valent iron，ACFs-S-nZVI)，并考察了复合材料活化过一硫酸盐(peroxymonosulfate，PMS)降解三氯苯酚(trichlorophenol，TCP)的催化性能、反应机理及重复使用性能。材料表征结果表明，硫化不仅可以缓解nZVI的氧化，还可以加快nZVI的电子传输速率，而引入ACFs载体则极大地提高了硫化纳米零价铁(sulfidized nanoscale zero-valent iron，S-nZVI)的分散性和稳定性。通过条件探究实验发现，当反应条件设置为S/Fe比0.3、温度25 ℃、pH=6、催化剂投加量0.5 g·L⁻¹、PMS投加量0.5 mmol·L⁻¹时，ACFs-S-nZVI/PMS体系表现出最佳的催化性能，在30 min内即可去除99.14% 10 μmol·L⁻¹的TCP，显著优于未改性的样品。此外，该体系具有较宽的pH(2~10)适应范围、优异的抗离子干扰能力以及出色的重复使用性能。电子顺磁共振波谱(EPR)和自由基淬灭实验结果表明，羟基自由基(^•OH)、硫酸根自由基(SO₄^•−)和超氧自由基(O₂^•−)参与了ACFs-S-nZVI/PMS体系的催化反应。综上可知，ACFs-S-nZVI具有催化性能优异、稳定性高、环境适应性强等优点，在催化降解有机污染物方面表现出较好的应用前景。
- 三氯苯酚 /
- 硫化纳米零价铁 /
- 过一硫酸盐 /
- 活性炭纤维
Abstract: In order to cope with the problems of severe agglomeration, easy passivation and difficult recovery of nanoscale zero-valent iron (nZVI) during reaction process, the activated carbon fibers (ACFs) with large specific surface area and excellent chemical stability were taken as carriers, and sodium dithionite (Na₂S₂O₄) was taken as the sulfidation reagent to successfully fabricate activated carbon fibers-supported sulfidized nanoscale zero-valent iron composite (ACFs-S-nZVI). Subsequently, the catalytic performance, reaction mechanism and recycling performance of this composite catalyst on trichlorophenol (TCP) degradation by activating peroxymonosulfate (PMS) were further investigated. The results of material characterization showed that the deposited ferrous sulfide (FeS) during the vulcanization process could not only mitigate the oxidation of nZVI, but also accelerate the electron transfer rate of nZVI, and the introduction of ACFs carrier substantially improved the dispersion and stability of sulfidized nanoscale zero-valent iron (S-nZVI). Through operational condition experiments, it was found that the ACFs-S-nZVI/PMS system exhibited the best catalytic performance when the reaction conditions were set to S/Fe ratio of 0.3, 25 ℃, pH of 6, catalyst dosage of 0.5 g·L⁻¹ and PMS dosage of 0.5 mmol·L⁻¹, and 99.14% of TCP with a concentration of 10 μmol·L⁻¹ could be degraded within 30 min, which was significantly better than that of the unmodified sample. In addition, the system had a wide pH adaptation range (pH=2~10), an excellent anti-ion interference ability and an outstanding recycling performance. The electron paramagnetic resonance (EPR) spectroscopy and radical quenching experiments showed that hydroxyl radical (^•OH), sulfate radical (SO₄^•−) and superoxide radical (O₂^•−) participated in the catalytic reaction of ACFs-S-nZVI/PMS system. In summary, ACFs-S-nZVI has the advantages of excellent catalytic performance, high stability, and strong environmental adaptability. Therefore, it shows great application prospects in catalytic degradation of organic pollutants.
- trichlorophenol /
- sulfide nanoscale zero-valent iron /
- peroxymonosulfate /
- activated carbon fibers
图 1 催化剂的SEM图像和元素映射图像

Figure 1. SEM images and element mappings of the catalysts

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图 2 催化剂的XRD图谱和FT-IR光谱

Figure 2. XRD patterns and FT-IR spectra of the catalysts

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图 3 ACFs-S-nZVI的S/Fe比与不同催化反应体系对去除TCP的影响

Figure 3. Effects of ACFs-S-nZVI with different S/Fe ratios and different catalytic reaction systems on TCP removal

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图 4 温度、pH、催化剂用量和PMS浓度对ACFs-S-nZVI/PMS体系去除TCP的影响

Figure 4. Effects of temperature, pH, catalyst dosage and PMS dosage on TCP removal in ACFs-S-nZVI/PMS system

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图 5 ACFs-S-nZVI/PMS体系在阴离子、阳离子或HA中对去除TCP的影响及其对不同类型污染物的处理效果

Figure 5. Effect of ACFs-S-nZVI/PMS system on TCP removal in anion, cation or HA and its removal effect on different types of pollutants

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图 6 自由基淬灭对去除TCP的影响及ACFs-S-nZVI/PMS体系EPR图谱

Figure 6. Effect of radicals quenching on TCP removal and EPR spectra of ACFs-S-nZVI/PMS system

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图 7 反应前后ACFs-S-nZVI的XPS光谱

Figure 7. XPS spectra of ACFs-S-nZVI before and after reaction

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图 8 ACFs-S-nZVI和ACFs-nZVI的LSV和EIS图谱

Figure 8. LSV patterns and electrochemical impedance spectroscopy (EIS) of ACFs-S-nZVI and ACFs-nZVI

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图 9 ACFs-S-nZVI活化PMS去除TCP机理示意图

Figure 9. Mechanism of ACFs-S-nZVI activating PMS to remove TCP

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图 10 循环次数和老化处理对催化体系去除TCP的影响

Figure 10. Effect of cycle times and aging treatment on TCP removal in catalytic systems

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图 11 ACFs-S-nZVI/PMS体系对模拟废水中TCP的处理效果

Figure 11. Treatment effect of ACFs-S-nZVI/PMS system on TCP in simulated wastewater

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[1]	王双, 杜倩, 谭莉, 等. AgBr-WO₃/GO载流子转移增强及其可见光降解2, 4, 6-三氯苯酚[J]. 功能材料, 2022, 53(2): 2130-2134. doi: 10.3969/j.issn.1001-9731.2022.02.019
[2]	张万辉. 零价铁对2, 4-二氯酚的还原脱氯研究[J]. 广东化工, 2014, 41(13): 47-48. doi: 10.3969/j.issn.1007-1865.2014.13.023
[3]	LIANG J L, ZHOU Y. Iron-based advanced oxidation processes for enhancing sludge dewaterability: State of the art, challenges, and sludge reuse[J]. Water Research, 2022, 218: 118499. doi: 10.1016/j.watres.2022.118499
[4]	AHMED Y, ZHONG J X, YUAN Z G, et al. Roles of reactive oxygen species in antibiotic resistant bacteria inactivation and micropollutant degradation in Fenton and photo-Fenton processes[J]. Journal of Hazardous Materials, 2022, 430: 128408. doi: 10.1016/j.jhazmat.2022.128408
[5]	SUN Y M, ZHOU P, ZHANG P, et al. New insight into carbon materials enhanced Fenton oxidation: A strategy for green iron (III) /iron (II) cycles[J]. Chemical Engineering Journal, 2022, 450: 138423. doi: 10.1016/j.cej.2022.138423
[6]	MEYERSTEIN D. Re-examining Fenton and Fenton-like reactions[J]. Nature Reviews Chemistry, 2021, 5(9): 595-597. doi: 10.1038/s41570-021-00310-4
[7]	KAVITHA V, PALANIVELU K. Degradation of phenol and trichlorophenol by heterogeneous photo-Fenton process using granular ferric hydroxide^®: Comparison with homogeneous system[J]. International Journal of Environmental Science and Technology, 2016, 13(3): 927-936. doi: 10.1007/s13762-015-0922-y
[8]	WANG N N, ZHENG T, ZHANG G S, et al. A review on Fenton-like processes for organic wastewater treatment[J]. Journal of Environmental Chemical Engineering, 2016, 4(1): 762-787. doi: 10.1016/j.jece.2015.12.016
[9]	FAROOQI Z H, BEGUM R, NASEEM K, et al. Zero valent iron nanoparticles as sustainable nanocatalysts for reduction reactions[J]. Catalysis Reviews, 2022, 64(2): 286-355. doi: 10.1080/01614940.2020.1807797
[10]	LI Y R, ZHAO H-P, ZHU L Z. Remediation of soil contaminated with organic compounds by nanoscale zero-valent iron: a review[J]. Science of the Total Environment, 2021, 760: 143413. doi: 10.1016/j.scitotenv.2020.143413
[11]	XU B D, LI D C, QIAN T T, et al. Boosting the activity and environmental stability of nanoscale zero-valent iron by montmorillonite supporting and sulfidation treatment[J]. Chemical Engineering Journal, 2020, 387: 124063. doi: 10.1016/j.cej.2020.124063
[12]	LI J X, ZHANG X Y, SUN Y K, et al. Advances in sulfidation of zerovalent iron for water decontamination[J]. Environmental Science & Technology, 2017, 51(23): 13533-13544.
[13]	MO Y L, XU J, ZHU L Z. Molecular structure and sulfur content affect reductive dechlorination of chlorinated ethenes by sulfidized nanoscale zerovalent iron[J]. Environmental Science & Technology, 2022, 56(9): 5808-5819.
[14]	郭雅妮, 强雪妮, 李海红, 等. 不同预处理方法对活性炭纤维结构和吸附性能的影响[J]. 环境工程学报, 2016, 10(5): 2227-2232. doi: 10.12030/j.cjee.201412128
[15]	ZHANG C C, TIAN H F, WANG Z X, et al. Degradation of PAHs in soil by activated persulfate system with activated carbon supported iron-based bimetal[J]. Science of the Total Environment, 2023, 866: 161323. doi: 10.1016/j.scitotenv.2022.161323
[16]	DONG H R, DENG J M, XIE Y K, et al. Stabilization of nanoscale zero-valent iron (nZVI) with modified biochar for Cr (VI) removal from aqueous solution[J]. Journal of Hazardous Materials, 2017, 332: 79-86. doi: 10.1016/j.jhazmat.2017.03.002
[17]	苏冰琴, 温宇涛, 林昱廷, 等. 改性活性炭纤维活化过硫酸盐深度处理焦化废水及降解吡啶的反应机制研究[J]. 中国环境科学, 2023, 43(2): 576-591. doi: 10.3969/j.issn.1000-6923.2023.02.010
[18]	甄建政, 聂士松, 潘世元, 等. 多维度碳基负载金属催化剂活化PMS降解水中污染物的研究进展[J]. 化工进展, 2022, 41(4): 1858-1872. doi: 10.16085/j.issn.1000-6613.2021-0738
[19]	TAN W T, RUAN Y, DIAO Z H, et al. Removal of levofloxacin through adsorption and peroxymonosulfate activation using carbothermal reduction synthesized nZVI/carbon fiber[J]. Chemosphere, 2021, 280: 130626. doi: 10.1016/j.chemosphere.2021.130626
[20]	杨思明, 刘爱荣, 刘静, 等. 硫化纳米零价铁研究进展: 合成、性质及环境应用[J]. 化学学报, 2022, 80(11): 1536-1554.
[21]	KONG A Q, LIU M H, ZHANG H J, et al. Highly selective electrocatalytic hydrogenation of benzoic acid over Pt/C catalyst supported on carbon fiber[J]. Chemical Engineering Journal, 2022, 445: 136719. doi: 10.1016/j.cej.2022.136719
[22]	SUN J A, WANG L X, WANG Y G, et al. Activation of peroxymonosulfate by MgCoAl layered double hydroxide: Potential enhancement effects of catalyst morphology and coexisting anions[J]. Chemosphere, 2022, 286: 131640. doi: 10.1016/j.chemosphere.2021.131640
[23]	XU J, AVELLAN A, LI H, et al. Sulfur loading and speciation control the hydrophobicity, electron transfer, reactivity, and selectivity of sulfidized nanoscale zerovalent iron[J]. Advanced Materials, 2020, 32(17): 1906910. doi: 10.1002/adma.201906910
[24]	XU J, AVELLAN A, LI H, et al. Iron and sulfur precursors affect crystalline structure, speciation, and reactivity of sulfidized nanoscale zerovalent iron[J]. Environmental Science & Technology, 2020, 54(20): 13294-13303.
[25]	XU Y N, WU Y T, LIU Y F, et al. Covering extracellular polymeric substances to enhance the reactivity of sulfidated nanoscale zerovalent iron toward Cr (VI) removal[J]. Chemical Engineering Journal, 2022, 448: 137610. doi: 10.1016/j.cej.2022.137610
[26]	DUAN X G, SU C, ZHOU L, et al. Surface controlled generation of reactive radicals from persulfate by carbocatalysis on nanodiamonds[J]. Applied Catalysis B: Environmental, 2016, 194: 7-15. doi: 10.1016/j.apcatb.2016.04.043
[27]	LI J W, ZOU J, ZHANG S Y, et al. Sodium tetraborate simultaneously enhances the degradation of acetaminophen and reduces the formation potential of chlorinated by-products with heat-activated peroxymonosulfate oxidation[J]. Water Research, 2022, 224: 119095. doi: 10.1016/j.watres.2022.119095
[28]	李广英, 杜敏洁, 谈成英, 等. 锰铁氧体活化PMS降解双酚A的过程机制[J]. 环境工程学报, 2021, 15(9): 2952-2962.
[29]	DU J K, BAO J G, LU C H, et al. Reductive sequestration of chromate by hierarchical FeS@Fe (0) particles[J]. Water Research, 2016, 102: 73-81. doi: 10.1016/j.watres.2016.06.009
[30]	姚梦东, 岳俊杰, 徐雪婧, 等. 球磨硫化零价铁活化过硫酸盐降解水体中有机氯农药[J]. 环境工程学报, 2021, 15(8): 2563-2575. doi: 10.12030/j.cjee.202103052
[31]	李鑫, 尹华, 罗昊昱, 等. 磁性生物炭负载α-MnO₂活化过一硫酸盐降解2, 2′, 4, 4′-四溴联苯醚[J]. 环境科学, 2021, 42(10): 4798-4806.
[32]	LI D P, FENG Z Q, ZHOU B H, et al. Impact of water matrices on oxidation effects and mechanisms of pharmaceuticals by ultraviolet-based advanced oxidation technologies: A review[J]. Science of the Total Environment, 2022, 844: 157162. doi: 10.1016/j.scitotenv.2022.157162
[33]	ZHEN J Z, NIE S S, SUN J H, et al. Fe₃O₄ nanoparticles encapsulated in boron nitride support via N-doped carbon layer as a peroxymonosulfate activator for pollutant degradation: Important role of metal boosted C–N sites[J]. Journal of Environmental Management, 2022, 311: 114859. doi: 10.1016/j.jenvman.2022.114859
[34]	杨佩汶, 林毅, 林华, 等. 不同构型人工湿地-微生物燃料电池对废水中对氯苯酚的净化效果及产电性能的影响[J]. 环境工程学报, 2023, 17(2): 507-516. doi: 10.12030/j.cjee.202210035
[35]	魏博. 大气和造纸废水中甲氧基苯酚类污染物去除机制的理论研究[D]. 济南: 山东大学, 2021.
[36]	DE FARIAS M B, PREDIGER P, VIEIRA M G A. Conventional and green-synthesized nanomaterials applied for the adsorption and/or degradation of phenol: A recent overview[J]. Journal of Cleaner Production, 2022, 367: 132980. doi: 10.1016/j.jclepro.2022.132980
[37]	FANG C, HAO Z X, WANG Y L, et al. Carbon nanotube as a nanoreactor for efficient degradation of 3-aminophenol over CoO_x/CNT catalyst[J]. Journal of Cleaner Production, 2023, 405: 136912. doi: 10.1016/j.jclepro.2023.136912
[38]	窦欣, 田乔鹏, 王琦, 等. Ganoderma sp. SYBC L48漆酶酶学性质及其对酸性红1的脱色性能[J]. 环境工程学报, 2019, 13(4): 856-864. doi: 10.12030/j.cjee.201809095
[39]	李新欣. 稻壳生物炭吸附水中对硝基苯酚和硝基苯的研究[D]. 南京: 南京信息工程大学, 2023.
[40]	CHEN Q, MA C R, DUAN W Y, et al. Coupling adsorption and degradation in p-nitrophenol removal by biochars[J]. Journal of Cleaner Production, 2020, 271: 122550. doi: 10.1016/j.jclepro.2020.122550
[41]	TANG N N, QIAN C B, ZHANG C W, et al. Isolation anchoring strategy for fabricating high-loading uniformly dispersed iron-based catalysts toward selective removal of phenolic compounds[J]. Separation and Purification Technology, 2023, 326: 124789. doi: 10.1016/j.seppur.2023.124789
[42]	CHEN L K, HUANG Y F, ZHOU M L, et al. Nitrogen-doped porous carbon encapsulating iron nanoparticles for enhanced sulfathiazole removal via peroxymonosulfate activation[J]. Chemosphere, 2020, 250: 126300. doi: 10.1016/j.chemosphere.2020.126300
[43]	LIU X R, LIU Y, QIN H H, et al. Selective removal of phenolic compounds by peroxydisulfate activation: Inherent role of hydrophobicity and interface ROS[J]. Environmental Science & Technology, 2022, 56(4): 2665-2676.
[44]	WANG M X, WANG Y G, SUN J H, et al. Layered double hydroxide/carbonitride heterostructure with potent combination for highly efficient peroxymonosulfate activation[J]. Chemosphere, 2023, 313: 137394. doi: 10.1016/j.chemosphere.2022.137394
[45]	DONG H Y, LI Y, WANG S C, et al. Both Fe (IV) and radicals are active oxidants in the Fe (II) /peroxydisulfate process[J]. Environmental Science & Technology Letters, 2020, 7(3): 219-224.
[46]	胡彩萍, 锁进然, 丁冠涛, 等. 草酸强化天然铁矿石异相光助Fenton催化降解萘酚[EB/OL]. [2023-07-06]中国环境科学. DOI: 10.19674/j.cnki.issn1000-6923.20230508.001.
[47]	WU L B, LIN Q T, FU H Y, et al. Role of sulfide-modified nanoscale zero-valent iron on carbon nanotubes in nonradical activation of peroxydisulfate[J]. Journal of Hazardous Materials, 2022, 422: 126949. doi: 10.1016/j.jhazmat.2021.126949
[48]	GAO F L, AHMAD S, TANG J C, et al. Enhanced nitrobenzene removal in soil by biochar supported sulfidated nano zerovalent iron: Solubilization effect and mechanism[J]. Science of the Total Environment, 2022, 826: 153960. doi: 10.1016/j.scitotenv.2022.153960
[49]	LING C, WU S, HAN J A, et al. Sulfide-modified zero-valent iron activated periodate for sulfadiazine removal: Performance and dominant routine of reactive species production[J]. Water Research, 2022, 220: 118676. doi: 10.1016/j.watres.2022.118676
[50]	JIANG Q, JIANG S M, LI H, et al. A stable biochar supported S-nZVI to activate persulfate for effective dichlorination of atrazine[J]. Chemical Engineering Journal, 2022, 431: 133937. doi: 10.1016/j.cej.2021.133937
[51]	ZHANG C, LU J, WU J. One-step green preparation of magnetic seaweed biochar/sulfidated Fe⁰ composite with strengthen adsorptive removal of tetrabromobisphenol A through in situ reduction[J]. Bioresource Technology, 2020, 307: 123170. doi: 10.1016/j.biortech.2020.123170
[52]	MI X Y, WANG P F, XU S Z, et al. Almost 100% peroxymonosulfate conversion to singlet oxygen on single‐atom CoN₂₊₂ sites[J]. Angewandte Chemie International Edition, 2021, 60(9): 4588-4593. doi: 10.1002/anie.202014472
[53]	XU Y, GUO Q, LI Y, et al. Stabilization of nano zero-valent iron by electrospun composite mat with good catalysis and recyclability[J]. Journal of Cleaner Production, 2022, 363: 132459. doi: 10.1016/j.jclepro.2022.132459
[54]	QIN X D, LI Z K, ZHU Z W, et al. Mechanism and kinetics of treatment of acid orange II by aged Fe-Si-B metallic glass powders[J]. Journal of Materials Science & Technology, 2017, 33(10): 1147-1152.
[55]	WANG J H, DUAN H Y, WANG M X, et al. Construction of durable superhydrophilic activated carbon fibers based material for highly-efficient oil/water separation and aqueous contaminants degradation[J]. Environmental Research, 2021, 207: 112212.
[56]	DENG J M, CHEN T, ARBID Y, et al. Aging and reactivity assessment of nanoscale zerovalent iron in groundwater systems[J]. Water Research, 2022, 229: 119472.
[57]	XU J, WANG Y, WENG C, et al. Reactivity, selectivity, and long-term performance of sulfidized nanoscale zerovalent iron with different properties[J]. Environmental Science & Technology, 2019, 53(10): 5936-5945.
[58]	陈砚田, 郄晗彤, 张胤杰, 等. 还原氧化石墨烯负载零价铁的合成及对TNT废水处理[J]. 高等学校化学学报, 2020, 41(8): 1836-1842. doi: 10.7503/cjcu20200198

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水是人类生存的基础性和战略性物资，而水污染则会直接影响人类的生命健康。酚类污染物是水体中常见的难降解且有毒有害的污染物之一，其中三氯苯酚(trichlorophenol，TCP)因其高毒性和致癌性已被列入中华人民共和国生态环境部、美国环境保护署和欧洲环境署发布的优先控制污染物目录。目前，处理这类污染物的方法主要有光降解法、化学还原法和吸附法等，然而，光降解法操作复杂成本高昂^[1]，化学还原法和吸附法处理效果较差^[2]，这些缺点导致它们在实际应用中受到一定程度的限制。

近年来，基于活性氧物种(reactive oxygen species，ROS)的高级氧化技术(advanced oxidation processes，AOPs)因其操作简单、反应速率高、对后续生化处理影响小等优点而受到人们的广泛关注^[3-4]。传统的芬顿氧化法是目前研究与应用中最成熟的高级氧化技术之一，主要利用Fe(Ⅱ)与过氧化氢(hydrogen peroxide，H₂O₂)间的反应生成具有强氧化性的羟基自由基(^•OH)，从而对各类有机物进行有效降解^[5-6]。但在均相体系中，催化剂回收利用难、反应所需pH受限、反应后产生的铁泥易造成二次污染等问题难以解决。针对这些缺陷，研究者逐渐采用含金属的非均相催化剂来替代传统金属离子进行催化反应^[7-8]。其中，纳米零价铁(nanoscale zero-valent iron，nZVI)具有还原能力强，成本低，环境友好等优点，是一种理想的非均相催化剂金属^[9]。然而，nZVI颗粒因其表面能高、稳定性差而易发生团聚和钝化，这导致其催化性能下降，故有必要对nZVI进行合理的修饰和改性，以提高nZVI的分散性和稳定性^[10]。

近期研究表明，nZVI的硫化产物(sulfidized nanoscale zero-valent iron，S-nZVI)能有效提高nZVI的催化活性^[11]。该硫化过程是在nZVI表面包裹一层硫化亚铁(FeS)，FeS作为屏障保护nZVI，可以减缓nZVI的氧化速率；同时，FeS具有的低电位还可以改善nZVI的电子传输性能^[12-13]。然而，在实际应用中，S-nZVI仍然存在易团聚、难回收等缺点。为此，有必要将金属负载在石墨烯、生物碳、膨润土等基体上，进一步提高其分散性和重复使用性。活性炭纤维(activated carbon fibers，ACFs)是一种高微孔碳质载体，与其它载体相比，具有较大的比表面积、丰富的反应性官能团(—COOH、C＝C、C—OH和C＝O等)以及廉价易回收等性质^[14]。在ACFs上负载nZVI能有效提高nZVI的分散性，同时，这种块状的催化材料具有宏观立体结构，回收利用性好，在实际应用中具有独特的优势^[15-18]。而协同硫化负载，将S-nZVI负载于ACFs制备得到的活性炭纤维负载硫化纳米零价铁(activated carbon fibers supported sulfidized nanoscale zero-valent iron，ACFs-S-nZVI)，则不仅解决了S-nZVI易团聚、难回收的问题，还有望提升S-nZVI的循环使用性能。但迄今为止，还未有关于ACFs-S-nZVI复合材料用于去除水体中有机污染物的报道。

因此，将深入探索ACFs-S-nZVI复合材料的结构与性能之间的关系，并将其用于活化过一硫酸盐(peroxymonosulfate，PMS)降解废水中的TCP。本研究详细探究了硫铁比、反应温度、pH、催化剂和氧化剂投加量等对ACFs-S-nZVI催化性能的影响。同时，通过大量的对比实验和电子顺磁共振波谱(EPR)分析探讨了ACFs-S-nZVI活化PMS降解去除TCP的反应机理。

1. 材料与方法

1.1. 实验试剂

七水合硫酸亚铁(FeSO₄·7H₂O)、连二亚硫酸钠(Na₂S₂O₄)和5，5-二甲基-1-吡咯啉-N-氧化物(5,5-dimethyl-1-pyrroline N-oxide，DMPO)购自上海麦克林生化科技有限公司，2，2，6，6-四甲基-4-哌啶酮(2,2,6,6-tetramethylpiperidine，TEMP)购自萨恩化学技术(上海)有限公司，硫酸(H₂SO₄)和硼氢化钠(NaBH₄)购自永华化学股份有限公司，氢氧化钠(NaOH)和无水乙醇(C₂H₅OH)购自北京化工厂，商业用铁碳催化剂购自天龙净水材料厂，ACFs购自江苏苏通碳纤维有限公司，厚度为0.3~0.4 cm，比表面积为900 m²·g⁻¹。

1.2. 催化剂制备

ACFs-S-nZVI等材料的制备：取一定量的ACFs浸入硝酸溶液(3 mol·L⁻¹)，然后在25 °C水浴摇床中振荡24 h，取出后用去离子水多次浸泡洗涤，置于60 ℃烘箱中干燥18 h后备用。准确称量100 mL去离子水倒入三颈烧瓶，然后在氮气环境下顺序加入1 g FeSO₄·7H₂O和1 g处理后的ACFs，以300 r·min⁻¹转速搅拌2 h后，逐滴加入80 mL 1 g NaBH₄和0.1 g Na₂S₂O₄的混合溶液，继续搅拌30 min后，将取出的催化剂用去离子水和无水乙醇交替洗涤至少3次，随后置于60 ℃真空烘箱中干燥6 h。最后得到的块状黑色纤维就是S/Fe比为0.3的ACFs-S-nZVI。此外，通过相同条件制备未加Na₂S₂O₄的ACFs-nZVI和未加ACFs的S-nZVI。

1.3. 催化降解实验

取20 mL浓度为10 μmol·L⁻¹的TCP溶液放入锥形瓶中，用H₂SO₄和NaOH调节溶液pH，并加入一定量的PMS和ACFs-S-nZVI，然后将锥形瓶置于恒温振荡器中，调节反应温度至一定值，设置转速150 r·min⁻¹，分别于5、10、15、20、25、30 min时取样2 mL，并经0.22 μm滤膜过滤，然后用高效液相色谱仪(HPLC)测定滤液中TCP的含量。每组实验设2个平行样。常规实验中，反应条件设置为温度25 ℃、pH=6、TCP浓度10 μmol·L⁻¹、催化剂投加量0.5 g·L⁻¹、PMS投加量0.5 mmol·L⁻¹。

1.4. 分析方法

TCP浓度用液相色谱仪(Waters 2 707)测定，流动相为甲醇和去离子水溶液(V∶V=80∶20)，流速0.2 mL·min⁻¹，柱温35 ℃，进样10 µL，检测波长295 nm。溶液中的铁离子浓度用硫氰化钾(KSCN)紫外分光光度法测定，PMS浓度用碘化钾(KI)和KSCN紫外分光光度法测定。

1.5. 材料表征

采用场发射扫描电子显微镜(FE-SEM，Vltra55)和能谱仪(EDS)观察S-nZVI及ACFs-S-nZVI的形貌和元素分布。采用X粉末衍射仪(XRD，Ultima Ⅳ)对样品的晶体结构、组成进行测试。测试条件为Cu-Kα(40 kV，40 mA)，额定输出功率为3 KW，扫描角度2θ为10°~80°，扫描速度为5 °·min⁻¹。采用傅里叶变换红外光谱仪(FT-IR，Nicolet 5700)对样品进行扫描，扫描波数为600~4 000 cm⁻¹，分辨率为4 cm⁻¹。采用X射线光电子能谱仪(XPS，Thermo K-Alpha)对样品在反应前后表面元素组成及价态的变化进行测试及分析。

1.6. 电化学分析

利用电化学工作站(CHI 604E)进行电化学测试，测试采用三电极系统，分别以铂片、饱和甘汞电极和玻碳电极作为对电极、参比电极和工作电极，所用电解液为1 mol·L⁻¹ KOH溶液。为制得所用的ACFs-S-nZVI和ACFs-nZVI改性后的玻碳电极，取1 mg充分研磨后的催化剂均匀分散在稀的Nafion溶液(0.5%，50 µL)中，然后取24 µL(分12次，每次2 µL)混合后的溶液滴在干净电极上，空气晾干后备用。

线性扫描伏安法(LSV)：搭建电化学测试装置，然后选择LSV模式，设置电位区间(3~-3 V)和扫描速率(50 mV·s⁻¹)等参数，测试开始后电压将从起始电位向终点电位进行单向扫描，最终得到的电极电流随电极电位变化的曲线即为线性扫描伏安图。

电化学阻抗技术(EIS)：搭建电化学测试装置，先确定开路电压，然后选择EIS模式将其设为初始电压，同时设置高频处频率(100 KHz)、低频处频率(1 Hz)以及振幅(0.005 V)等参数，最终得到的不同频率下阻抗的实部Z'和虚部Z''绘制的曲线即为电化学阻抗谱。

1.7. EPR测试

在1 mL反应溶液中加入适量DMPO或TEMP作为捕获剂，混合均匀，用毛细管取适量混合溶液放入电子顺磁共振波谱仪中，仪器参数设定为：中心场3 510 G，扫描宽度为80 G，微波频率为9.77 GHz，功率为20.00 mW。利用EPR鉴定ACFs-S-nZVI/PMS体系中产生的自旋加合物特征峰，从而进一步判断体系中产生的ROS。

3. 结论

1)硫掺杂和以ACFs作为载体可以显著提升nZVI的催化性能，改性后的催化剂颗粒不仅变得更加分散和均匀，而且直径得到显著减小。

2)当反应条件设置为S/Fe比0.3、温度25 ℃、pH=6、催化剂投加量0.5 g·L⁻¹、PMS投加量0.5 mmol·L⁻¹时，ACFs-S-nZVI/PMS体系在30 min内即可去除99.14%的TCP(10 μmol·L⁻¹)，明显优于改性前的催化体系。

3) ^•OH、SO₄^•−和O₂^•−在ACFs-S-nZVI/PMS体系去除TCP中发挥着重要作用；硫化能显著提高ACFs-S-nZVI的电子传递能力。

4) ACFs-S-nZVI/PMS体系在去除TCP(10 μmol·L⁻¹)时表现出了优异的酸碱耐受性(pH=2~10)和抗离子干扰性；即使经过5次循环或不同的老化处理后，也仍能达到90%左右的TCP去除率；在处理模拟TCP(10 mg·L⁻¹)废水时，效果同样较好，表明ACFs-S-nZVI/PMS体系在废水的实际处理中具有广阔的应用前景。

参考文献 (58)

活性炭纤维负载硫化纳米零价铁用于活化PMS降解三氯苯酚

作者简介: 张子薇 (1999—) ，女，硕士研究生，202130302215@mails.zstu.edu.cn

通讯作者: 吕维扬(1991—)，男，博士，副研究员，wylv@zstu.edu.cn

Degradation of trichlorophenol by activated carbon fibers-supported S-nZVI activating PMS

Corresponding author: LYU Weiyang, wylv@zstu.edu.cn

计量

活性炭纤维负载硫化纳米零价铁用于活化PMS降解三氯苯酚

通讯作者: 吕维扬(1991—)，男，博士，副研究员，wylv@zstu.edu.cn

作者简介: 张子薇 (1999—) ，女，硕士研究生，202130302215@mails.zstu.edu.cn
1. 浙江理工大学材料科学与工程学院，纺织纤维材料与加工技术国家地方联合工程实验室，杭州 310018

2. 浙江省现代纺织技术创新中心，绍兴 312000

English Abstract

Degradation of trichlorophenol by activated carbon fibers-supported S-nZVI activating PMS

Corresponding author: LYU Weiyang, wylv@zstu.edu.cn

全文HTML

1.1. 实验试剂

1.2. 催化剂制备

1.3. 催化降解实验

1.4. 分析方法

1.5. 材料表征

1.6. 电化学分析

1.7. EPR测试

2.1. 材料表征

2.2. ACFs-S-nZVI活化PMS降解TCP

2.3. 反应参数对ACFs-S-nZVI材料催化性能的影响

2.4. ACFs-S-nZVI/PMS体系的稳定性和适用性研究

2.5. ACFs-S-nZVI/PMS体系反应机理

2.6. 模拟实际应用

目录

活性炭纤维负载硫化纳米零价铁用于活化PMS降解三氯苯酚

作者简介: 张子薇 (1999—) ，女，硕士研究生，202130302215@mails.zstu.edu.cn

通讯作者: 吕维扬(1991—)，男，博士，副研究员，wylv@zstu.edu.cn

Degradation of trichlorophenol by activated carbon fibers-supported S-nZVI activating PMS

Corresponding author: LYU Weiyang, wylv@zstu.edu.cn

计量

出版历程

活性炭纤维负载硫化纳米零价铁用于活化PMS降解三氯苯酚

通讯作者: 吕维扬(1991—)，男，博士，副研究员，wylv@zstu.edu.cn

作者简介: 张子薇 (1999—) ，女，硕士研究生，202130302215@mails.zstu.edu.cn 1. 浙江理工大学材料科学与工程学院，纺织纤维材料与加工技术国家地方联合工程实验室，杭州 310018 2. 浙江省现代纺织技术创新中心，绍兴 312000

English Abstract

Degradation of trichlorophenol by activated carbon fibers-supported S-nZVI activating PMS

Corresponding author: LYU Weiyang, wylv@zstu.edu.cn

全文HTML

1.1. 实验试剂

1.2. 催化剂制备

1.3. 催化降解实验

1.4. 分析方法

1.5. 材料表征

1.6. 电化学分析

1.7. EPR测试

2.1. 材料表征

2.2. ACFs-S-nZVI活化PMS降解TCP

2.3. 反应参数对ACFs-S-nZVI材料催化性能的影响

2.4. ACFs-S-nZVI/PMS体系的稳定性和适用性研究

2.5. ACFs-S-nZVI/PMS体系反应机理

2.6. 模拟实际应用

目录

作者简介: 张子薇 (1999—) ，女，硕士研究生，202130302215@mails.zstu.edu.cn
1. 浙江理工大学材料科学与工程学院，纺织纤维材料与加工技术国家地方联合工程实验室，杭州 310018

2. 浙江省现代纺织技术创新中心，绍兴 312000