姚绍武1a,2 ,钱伟民2 ,王誉博1a ,胡小龙1a ,张文彬2 ,宋俊颖1b ,董雄波3
1. 山东科技大学 a. 能源与矿业工程学院, b. 安全与环境工程学院,山东 青岛 266590;2. 湖州新开元碎石有限公司,浙江 湖州 313002;3. 中国地质大学(武汉) 教育部纳米地质材料工程研究中心,湖北 武汉 430074
引用格式:
姚绍武,钱伟民,王誉博,等. CuO-高岭石活化PMS降解诺氟沙星性能[J]. 中国粉体技术,2024,30(6):1-12.
YAO Shaowu, QIAN Weimin, WANG Yubo, et al. Catalytic performance of CuO-kaolinite composite for norfloxacin degradation by activating peroxymonosulfate[J]. China Powder Science and Technology,2024,30(6):1−12.
DOI:10.13732/j.issn.1008-5548.2024.06.006
收稿日期:2023-10-19,修回日期:2024-05-17,上线日期:2024-10-30。
基金项目:国家自然科学基金项目,编号:52204289;山东省自然科学基金项目,编号:ZR2022QE236;青岛市自然科学基金项目,编号:23-2-1-107-zyyd-jch
第一作者简介:姚绍武(1977—),男,硕士,教授级高级工程师,研究方向为非金属矿山的绿色建设和矿山资源的高值化利用。E-mail:1207768437@qq. com。
通信作者简介:胡小龙(1989—),男,讲师,博士,硕士生导师,研究方向为非金属矿物功能材料。E-mail:xiaolonghu@sdust. edu. cn。
摘要:【目的】 为解决纯过硫酸盐催化剂在制备过程中易团聚的问题,分析引入高岭石载体后催化剂的结构和催化性能的变化规律,实现对抗生素废水中有机污染物的高效降解。【方法】 首先以高岭石为载体,采用水热煅烧法制备了CuO-高岭石复合材料。使用物相分析、 X射线光电子谱、扫描电子显微镜和氮吸附仪等对材料的晶体结构、表面化学态、微观形貌、比表面积以及孔结构特征进行了表征,考察不同 CuO与高岭石质量比、催化剂用量和过一硫酸盐(peroxymono⁃sulfate,PMS)用量对NOR降解效率的影响,进行实验条件优化,并系统分析CuO-高岭石复合材料催化PMS降解NOR的机制。【结果】 CuO 与高岭石质量比为 40% 时 CuO-高岭石复合材料具有最优的催化性能,在催化剂用量为 1. 5 g/L,PMS用量为 1. 0 mmol/L,NOR初始质量浓度为 10 mg/L,反应时间为 60 min时,NOR的降解效率为 76. 21%; CuO-高岭石中Cu(I)、 Cu(II)之间的价态循环参与了PMS的活化,反应体系中主要的活性物种是单线态氧1 O2,而超氧自由基O2 •-、硫酸根自由基SO4 •-和羟基自由基• OH也参与了NOR降解过程。【结论】 CuO-高岭石复合材料中,CuO纳米片能够均匀地分散并沉积在高岭石载体表面,显著减少了 CuO 纳米片的相互团聚,使得更多反应活性位点暴露,增强了复合材料对PMS的活化能力和对NOR的降解能力。
Objective Due to the overuse of pharmaceutical antibiotics, residues have been frequently detected in different environmental matrices, including surface water, sewage, and soils. The presence of antibiotics in environment can cause potential adverse effects on human and ecological system due to their acute and chronic toxicity and the development of antibiotic resistance. However, traditional wastewater purification technologies are ineffective in eliminating antibiotics. In recent years, the advanced oxidation process (AOP) based on sulfate radicals has been confirmed as the most suitable and efficient way to remove such pollutants from wastewater. The CuO-peroxymonosulfate (PMS) system, in particular, has gained considerable attention due to its strong oxidation ability. Nevertheless, the high surface energy of CuO often leads to aggregation during the synthesis process,reducing the amount of active sites and specific surface area. To address this problem, kaolinite was introduced as a support for CuO in this study, and changes in the structure and catalytic performance of the CuO-kaolinite catalyst were analyzed to achieve efficient degradation of organic pollutants in antibiotic wastewater.
Methods In this paper, CuO-kaolinite composite was fabricated using a hydrothermal calcination method. Initially,1. 0 g of sepiolite was mixed with 50 mL of distilled water and stirred for 0. 5 h. Then, different amounts of Cu (NO3)2 ·3H2O were added to the solution and stirred for 10 min. Subsequently, an ammonia-water solution (v:v=1:1) was added drop-wise to adjust the pH value to 7. 5~8 at room temperature. After stirring for 15 min, the mixture was transferred into a 100 mL Teflon-lined stainless-steel autoclave and heated at 150 ℃ for 5 h. The resulting products were washed, dried, ground, and then calcined in a muffle furnace at 250 ℃ for 3 h. Finally, after simple grinding, the CuO-kaolinite composite with different mass ratios of CuO and kaolinite was synthesized. The crystal structure, surface chemical state, microstructure, specific surface area,
Results and discussion The effects of different mass ratios of CuO and kaolinite, catalyst dosages, PMS dosages, initial concentration of norfloxacin (NOR), initial pH of the solution, and coexisting anions on the degradation efficiency of NOR were investigated. The experimental results indicated that higher NOR degradation efficiency was achieved with the CuO-kaolinite-PMS system compared to other oxidation systems. Specifically, when the mass ratio of CuO and kaolinite was 40%, the CuO-kaolinite composite exhibited optimal catalytic performance. At a catalyst dosage of 1. 5 g/L, a PMS dosage of 1. 0 mmol/L, and an initial NOR concentration of 10 mg/L, the degradation efficiency of NOR after reacting for 60 min was about 76. 21%. An increase in catalyst dosage initially led to a significant enhancement in NOR degradation efficiency, followed by a slight increase, while excessive PMS had an inhibitory effect. A higher initial concentration of NOR gradually decreased its degradation efficiency. Within a wide pH range, high NOR removal efficiency was achieved in the composite-PMS system, demonstrating its good practical application potential. The coexisting Cl-, HCO3-, and H2PO4-in this system exhibited inhibitory effects on the NOR degradation, while NO3- had a relatively minor impact. In addition, the catalytic mechanism of the CuO-kaolinite composite for NOR degradation was systematically analyzed, revealing that the valence cycle between the Cu2+ and Cu+ in CuO-kaolinite composite was involved in the activation of PMS. The main active species in the reaction system were singlet oxygen (1 O2), while superoxide radicals (O2 •-), sulfate radicals (SO4 •-), and hydroxyl radicals (• OH) also contributed to the NOR degradation.
Conclusion The introduction of kaolinite carriers allows for the formation of CuO nanosheets with smaller grain sizes, which are dispersed and deposited on the surface of kaolinite. The specific surface area and pore volume of the composite are greater than those of pure CuO. In CuO-kaolinite composite, CuO nanosheets are uniformly dispersed and deposited on the surface of kaolinite carriers, significantly reducing their self-aggregation and exposing more reactive sites, thereby enhancing the activation efficiency of PMS. As a result, more active species, such as1O2, O2 •-, SO4 •-, and•OH, are continuously produced, which contributes to the NOR degradation. In summary, this work provides a new approach for the structure design and preparation of mineral-based PMS catalysts with efficient catalytic performance and adsorption capacity, guiding their application in antibiotic wastewater treatment.
Keywords:CuO; kaolinite; peroxymonosulfate; norfloxacin
[1]李英豪,郑向前,高晓亚,等. CoFe2O4的制备及其活化过一硫酸盐降解磺胺甲噁唑[J]. 精细化工,2022,39(5):1020-1027.
LI L H, ZHENG X Q, GAO X Y, et al. Preparation of CoFe2O4and the degradation of sulfamethoxazole by activating persulfate [J]. Fine Chemicals,2022,39(5):1020-1027.
[2]田婷婷, 李朝阳, 王召东, 等. 过渡金属活化过硫酸盐降解有机废水技术研究进展[J]. 化工进展, 2021, 40(6):3480-3488.
TIAN T T, LI C Y, WANG Z D, et al. Research progress on transition metal activating persulfate degradation technology for organic wastewater [J]. Chemical Industry and Engineering Progress,2021,40(6):3480-3488.
[3]XIN J Y, LIU Y, NIU L Y, et al. Three-dimensional porous CuFe2O4 for visible-light-driven peroxymonosulfate activation with superior performance for the degradation of tetracycline hydrochloride [J]. Chemical Engineering Journal,2022,445:16.
[4]WEI Y F, LIU H, LIU C B, et al. Fast and efficient removal of As(III) from water by CuFe2O4 with peroxymonosulfate:effects of oxidation and adsorption [J]. Water Research,2019,150:182-190.
[5]DONG X B, REN B X, SUN Z M, et al. Monodispersed CuFe2O4 nanoparticles anchored on natural kaolinite as highly efficient peroxymonosulfate catalyst for bisphenol a degradation[J]. Applied Catalysis B-Environmental,2019,253:206-217.
[6]HUANG Q L, CHEN C J, ZHAO X L, et al. Malachite green degradation by persulfate activation with CuFe2O4 @biochar composite: efficiency, stability and mechanism [J]. Journal of Environmental Chemical Engineering,2021,9(4):10.
[7]REN B, MIN F F, LIU L Y, et al. Adsorption of different PAM structural units on kaolinite (001) surface: density functional theory study [J]. Applied Surface Science,2020,504:144324.
[8]刘杰,曹亦俊,李晓恒,等. 溶液环境对高岭石分散行为的影响[J]. 矿产保护与利用,2017(4):35-39.
LIU J, CAO Y J, LI X H, et al. The influence of solution environment on the dispersion behavior of kaolinite [J]. Conservation and Utilization of Mineral Resources,2017(4):35-39.
[9]卢承龙, 苟晓琴, 韩海生, 等. 天然铝硅酸盐矿物对氟离子的吸附性能研究[J]. 矿产保护与利用, 2020, 40(1):28-36.
LU C L, GOU X Q, HAN H S, et al. Study on the adsorption performance of natural aluminosilicate minerals for fluoride ions[J]. Conservation and Utilization of Mineral Resources,2020,40(1):28-36.
[10]LIU Q H, WANG S, HAN F, et al. Biomimetic tremelliform ultrathin MnO2/CuO nanosheets on kaolinite driving superior catalytic oxidation: an example of CO [J]. ACS Applied Materials & Interfaces,2022,14(39):44345-44357.
[11]陈锦富,严群,龚鹏程,等. CuFe2O4/硅藻土复合材料活化过一硫酸盐降解酸性橙[J]. 精细化工,2023,40(9):2042-2051.
CHEN J F, YAN Q, GONG P C, et al. CuFe2O4/diatomite composite material activated peroxymonosulfate degradation of acid orange [J]. Fine Chemicals,2023,40(9):2042-2051.
[12]ZHANG Z, DAI Y Z. Co3O4 /C-PC composite derived from pomelo peel-loaded ZIF-67 for activating peroxymonosulfate (PMS) to degrade ciprofloxacin [J]. Journal of Water Process Engineering,2022,49:103043.
[13]NI T J, ZHANG H, YANG Z B, et al. Enhanced adsorption and catalytic degradation of antibiotics by porous 0D/3D Co3O4/g-C3N4 activated peroxymonosulfate: an experimental and mechanistic study[J]. Journal of Colloid and Interface Science,2022,625:466-478.
[14]DONG X B, DUAN X D, SUN Z M, et al. Natural illite-based ultrafine cobalt oxide with abundant oxygen-vacancies for highly efficient fenton-like catalysis [J]. Applied Catalysis B: Environmental,2020,261:118214.
[15]GAO M C, YANG J X, SUN T, et al. Persian buttercup-like BiOBrxCl1-x solid solution for photocatalytic overall CO2 reduction to CO and O2 [J]. Applied Catalysis B: Environmental,2019,243:734-740.
[16]YANG L, CHEN Y, YANG D, et al. Mechanistic insights into adsorptive and oxidative removal of monochlorobenzene in biochar-supported nanoscale zero-valent iron/persulfate system [J]. Chemical Engineering Journal,2020,400:125811.
[17]REN X, WANG Y, HU G, et al. CoFe2O4 nanoparticles assembled on natural sepiolite fibers as peroxymonosulfate catalyst for efficient norfloxacin degradation [J]. Materials Research Bulletin,2024,169:112538.
[18]LI Z L, WANG M, JIN C Y, et al. Synthesis of novel Co3O4 hierarchical porous nanosheets via corn stem and MOF-Co templates for efficient oxytetracycline degradation by peroxymonosulfate activation [J]. Chemical Engineering Journal,2020,392:123789.
[19]WANG B Y, LI Q Q, LV Y, et al. Insights into the mechanism of peroxydisulfate activated by magnetic spinel CuFe2O4/ SBC as a heterogeneous catalyst for bisphenol S degradation [J]. Chemical Engineering Journal,2021,416:13.
[20]LI Z S, TANG X K, HUANG G H, et al. Bismuth MOFs based hierarchical Co3O4-Bi2O3 composite: an efficient heterogeneous peroxymonosulfate activator for AZO dyes degradation[J]. Separation and Purification Technology,2020,242:116825.
[21]SONG J Y, REN X F, HU G C, et al. Enhanced PMS activation by MOF-derived Co3O4/sepiolite composite for norfloxacin degradation: performance, mechanism and degradation pathway [J]. Process Safety and Environmental Protection,2023,176:140-154.
[22]AHMADI M, GHANBARI F. Combination of UVC-LEDs and ultrasound for peroxymonosulfate activation to degrade synthetic dye: influence of promotional and inhibitory agents and application for real wastewater [J]. Environmental Science and Pollution Research,2018,25(6):6003-6014.
