在不同水質參數下利用氧化銅活化過二硫酸鹽降解氯酚類有機污染物：透水性反應牆模組試驗

Chia-Chun Hsu; 許佳君

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/79580

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	林逸彬(Yi-Pin Lin)
dc.contributor.author	Chia-Chun Hsu	en
dc.contributor.author	許佳君	zh_TW
dc.date.accessioned	2022-11-23T09:04:16Z	-
dc.date.available	2021-11-08
dc.date.available	2022-11-23T09:04:16Z	-
dc.date.copyright	2021-11-08
dc.date.issued	2021
dc.date.submitted	2021-09-16
dc.identifier.citation	Reference Ahmad, M., Teel, A. L. and Watts, R. J. (2013). Mechanism of persulfate activation by phenols. Environ Sci Technol, 47(11), 5864-5871. Anipsitakis, G. P. and Dionysiou, D. D. (2003). Degradation of Organic Contaminants in Water with Sulfate Radicals Generated by the Conjunction of Peroxymonosulfate with Cobalt. Environ Sci Technol, VOL. 37, NO. 20. Anipsitakis, G. P. and Dionysiou, D. D. (2004). Radical Generation by the Interaction of Transition Metals with Common Oxidants. Environ Sci Technol, VOL. 38, NO. 13. Anipsitakis, G. P., Dionysiou, D. D. and Gonzalez, M. A. (2006). Cobalt-Mediated Activation of Peroxymonosulfate and Sulfate Radical Attack on Phenolic Compounds. Implications of Chloride Ions. Environ Sci Technol, VOL. 40, NO. 3. ASTM. (2006). Standard test methods for specific gravity of soil solids by water pycnometer: ASTM international. Bruton, T. A. and Sedlak, D. L. (2018). Treatment of perfluoroalkyl acids by heat-activated persulfate under conditions representative of in situ chemical oxidation. Chemosphere, 206, 457-464. Cao, M., Hou, Y., Zhang, E., Tu, S. and Xiong, S. (2019). Ascorbic acid induced activation of persulfate for pentachlorophenol degradation. Chemosphere, 229, 200-205. Chen, J., Zhou, X., Zhu, Y., Zhang, Y. and Huang, C. H. (2020). Synergistic activation of peroxydisulfate with magnetite and copper ion at neutral condition. Water Res, 186, 116371. Chen, L., Hu, X., Cai, T., Yang, Y., Zhao, R., Liu, C., Li, A. and Jiang, C. (2019). Degradation of Triclosan in soils by thermally activated persulfate under conditions representative of in situ chemical oxidation (ISCO). Chemical Engineering Journal, 369, 344-352. Chi, H., He, X., Zhang, J., Wang, D., Zhai, X. and Ma, J. (2019). Hydroxylamine enhanced degradation of naproxen in Cu2+ activated peroxymonosulfate system at acidic condition: Efficiency, mechanisms and pathway. Chemical Engineering Journal, 361, 764-772. Cho, Y. C., Lin, R. Y. and Lin, Y. P. (2020). Degradation of 2,4-dichlorophenol by CuO-activated peroxydisulfate: Importance of surface-bound radicals and reaction kinetics. Sci Total Environ, 699, 134379. Du, X., Zhang, Y., Hussain, I., Huang, S. and Huang, W. (2017). Insight into reactive oxygen species in persulfate activation with copper oxide: Activated persulfate and trace radicals. Chemical Engineering Journal, 313, 1023-1032. Du, X., Zhang, Y., Si, F., Yao, C., Du, M., Hussain, I., Kim, H., Huang, S., Lin, Z. and Hayat, W. (2019). Persulfate non-radical activation by nano-CuO for efficient removal of chlorinated organic compounds: Reduced graphene oxide-assisted and CuO (0 0 1) facet-dependent. Chemical Engineering Journal, 356, 178-189. Exner, M., Herrmann, H. and Zellner, R. (1992). Laser-Based Studies of Reactions of the Nitrate Radical in Aqueous Solution. Phys. Chem. 96, No.3. Fang, C., Lou, X., Huang, Y., Feng, M., Wang, Z. and Liu, J. (2017). Monochlorophenols degradation by UV/persulfate is immune to the presence of chloride: Illusion or reality? Chemical Engineering Journal, 323, 124-133. Fang, G., Liu, C., Gao, J., Dionysiou, D. D. and Zhou, D. (2015). Manipulation of persistent free radicals in biochar to activate persulfate for contaminant degradation. Environ Sci Technol, 49(9), 5645-5653. Fang, T. Y., He, Q., Si, S., Yang, J., Tu, X. and Khaletski, V. (2019). Application of permeable reactive barrier in groundwater remediation. E3S Web of Conferences, 136. Fu, C., Yi, X., Liu, Y. and Zhou, H. (2020). Cu(2+) activated persulfate for sulfamethazine degradation. Chemosphere, 257, 127294. Furman, O. S., Teel, A. L., Ahmad, M., Merker, M. C. and Watts, R. J. (2011). Effect of Basicity on Persulfate Reactivity. Journal of Environmental Engineering, 137(4), 241-247. Furman, O. S., Teel, A. L. and Watt, R. J. (2010). Mechanism of Base Activation of Persulfate. Environ Sci Technol, VOL. 44, NO. 16. Guan, Y. H., Ma, J., Li, X. C., Fang, J. Y. and Chen, L. W. (2011). Influence of pH on the formation of sulfate and hydroxyl radicals in the UV/peroxymonosulfate system. Environ Sci Technol, 45(21), 9308-9314. Hernández, P. C., Dupont, J., Herreros, O. O., Jimenez, Y. P. and Torres, C. M. (2019). Accelerating Copper Leaching from Sulfide Ores in Acid-Nitrate-Chloride Media Using Agglomeration and Curing as Pretreatment. Minerals, 9(4). Huang, K. C., Zhao, Z., Hoag, G. E., Dahmani, A. and Block, P. A. (2005). Degradation of volatile organic compounds with thermally activated persulfate oxidation. Chemosphere, 61(4), 551-560. Huling, S. G. and Pivetz, B. E. (2006). In-situ chemical oxidation. Retrieved from Igbinosa, E. O., Odjadjare, E. E., Chigor, V. N., Igbinosa, I. H., Emoghene, A. O., Ekhaise, F. O., Igiehon, N. O. and Idemudia, O. G. (2013). Toxicological profile of chlorophenols and their derivatives in the environment: the public health perspective. ScientificWorldJournal, 2013, 460215. Jawad, A., Zhan, K., Wang, H., Shahzad, A., Zeng, Z., Wang, J., Zhou, X., Ullah, H., Chen, Z. and Chen, Z. (2020). Tuning of Persulfate Activation from a Free Radical to a Nonradical Pathway through the Incorporation of Non-Redox Magnesium Oxide. Environ Sci Technol, 54(4), 2476-2488. Kim, C., Ahn, J. Y., Kim, T. Y., Shin, W. S. and Hwang, I. (2018). Activation of Persulfate by Nanosized Zero-Valent Iron (NZVI): Mechanisms and Transformation Products of NZVI. Environ Sci Technol, 52(6), 3625-3633. Kim, C., Thao, T. T., Kim, J. H. and Hwang, I. (2020). Effects of the formation of reactive chlorine species on oxidation process using persulfate and nano zero-valent iron. Chemosphere, 250, 126266. Lee, J., von Gunten, U. and Kim, J. H. (2020). Persulfate-Based Advanced Oxidation: Critical Assessment of Opportunities and Roadblocks. Environ Sci Technol, 54(6), 3064-3081. Lei, Y., Chen, C. S., Tu, Y. J., Huang, Y. H. and Zhang, H. (2015). Heterogeneous Degradation of Organic Pollutants by Persulfate Activated by CuO-Fe3O4: Mechanism, Stability, and Effects of pH and Bicarbonate Ions. Environ Sci Technol, 49(11), 6838-6845. Li, S., Li, W., Chen, H., Liu, F., Jin, S., Yin, X., Zheng, Y. and Liu, B. (2018). Effects of calcium ion and pH on the adsorption/regeneration process by activated carbon permeable reactive barriers. RSC Advances, 8(30), 16834-16841. Li, T., Zhang, C., Zhang, J., Yan, S. and Qin, C. (2020). Remediation of 2,4-dichlorophenol-contaminated groundwater using nano-sized CaO2 in a two-dimensional scale tank. Frontiers of Environmental Science Engineering, 15(5). Li, W., Orozco, R., Camargos, N. and Liu, H. (2017). Mechanisms on the Impacts of Alkalinity, pH, and Chloride on Persulfate-Based Groundwater Remediation. Environ Sci Technol, 51(7), 3948-3959. Li, X., Wu, B., Zhang, Q., Xu, D., Liu, Y., Ma, F., Gu, Q. and Li, F. (2019). Mechanisms on the impacts of humic acids on persulfate/Fe2+-based groundwater remediation. Chemical Engineering Journal, 378. Liang, C., Huang, C. F., Mohanty, N. and Kurakalva, R. M. (2008). A rapid spectrophotometric determination of persulfate anion in ISCO. Chemosphere, 73(9), 1540-1543. Liang, H.-y., Zhang, Y.-q., Huang, S.-b. and Hussain, I. (2013). Oxidative degradation of p-chloroaniline by copper oxidate activated persulfate. Chemical Engineering Journal, 218, 384-391. Liu, B., Li, Y. and Xing, S. (2020). Insight into the mechanism of CuO activated persulfate with the assistance of bicarbonate for removing organic pollutants. Journal of Water Process Engineering, 37. Liu, H., Bruton, T. A., Doyle, F. M. and Sedlak, D. L. (2014). In situ chemical oxidation of contaminated groundwater by persulfate: decomposition by Fe(III)- and Mn(IV)-containing oxides and aquifer materials. Environ Sci Technol, 48(17), 10330-10336. Liu, Y., Zhang, Y. and Zhou, A. (2019). A potential novel approach for in situ chemical oxidation based on the combination of persulfate and dithionite. Sci Total Environ, 693, 133635. Lutze, H. V., Bircher, S., Rapp, I., Kerlin, N., Bakkour, R., Geisler, M., von Sonntag, C. and Schmidt, T. C. (2015). Degradation of chlorotriazine pesticides by sulfate radicals and the influence of organic matter. Environ Sci Technol, 49(3), 1673-1680. Ma, J., Li, H., Yang, Y. and Li, X. (2018a). Influence of water matrix species on persulfate oxidation of phenol: reaction kinetics and formation of undesired degradation byproducts. Water Sci Technol, 2017(2), 340-350. Ma, J., Yang, Y., Jiang, X., Xie, Z., Li, X., Chen, C. and Chen, H. (2018b). Impacts of inorganic anions and natural organic matter on thermally activated persulfate oxidation of BTEX in water. Chemosphere, 190, 296-306. Matarredona, O., Rhoads, H., Li, Z., Harwell, J. H., Balzano, L. and Resasco, D. E. (2003). Dispersion of single-walled carbon nanotubes in aqueous solutions of the anionic surfactant NaDDBS. The Journal of Physical Chemistry B, 107(48), 13357-13367. Matta, R. and Chiron, S. (2018). Oxidative degradation of pentachlorophenol by permanganate for ISCO application. Environ Technol, 39(5), 651-657. Matzek, L. W. and Carter, K. E. (2016). Activated persulfate for organic chemical degradation: A review. Chemosphere, 151, 178-188. Neta, P., Huie, R. E. and Ross, A. B. (1988). Rate constants for reactions of inorganic radicals in aqueous solution. Journal of Physical and Chemical Reference Data, 17(3), 1027-1284. Obiri-Nyarko, F., Grajales-Mesa, S. J. and Malina, G. (2014). An overview of permeable reactive barriers for in situ sustainable groundwater remediation. Chemosphere, 111, 243-259. Oh, W.-D., Wong, Z., Chen, X., Lin, K.-Y. A., Veksha, A., Lisak, G., He, C. and Lim, T.-T. (2020). Enhanced activation of peroxydisulfate by CuO decorated on hexagonal boron nitride for bisphenol A removal. Chemical Engineering Journal, 393. Rayaroth, M. P., Oh, D., Lee, C. S., Kang, Y. G. and Chang, Y. S. (2020). In situ chemical oxidation of contaminated groundwater using a sulfidized nanoscale zerovalent iron-persulfate system: Insights from a box-type study. Chemosphere, 257, 127117. Shafirovich, V., Dourandin, A., Huang, W. and Geacintov, N. E. (2001). The carbonate radical is a site-selective oxidizing agent of guanine in double-stranded oligonucleotides. J Biol Chem, 276(27), 24621-24626. Thiruvenkatachari, R., Vigneswaran, S. and Naidu, R. (2008). Permeable reactive barrier for groundwater remediation. Journal of Industrial and Engineering Chemistry, 14(2), 145-156. Vaezihir, A., Bayanlou, M. B., Ahmadnezhad, Z. and Barzegari, G. (2020). Remediation of BTEX plume in a continuous flow model using zeolite-PRB. J Contam Hydrol, 230, 103604. Vračar, R. Ž., Vučković, N. and Kamberović, Ž. (2003). Leaching of copper(I) sulphide by sulphuric acid solution with addition of sodium nitrate. Hydrometallurgy, 70(1-3), 143-151. Wacławek, S., Lutze, H. V., Grübel, K., Padil, V. V. T., Černík, M. and Dionysiou, D. D. (2017). Chemistry of persulfates in water and wastewater treatment: A review. Chemical Engineering Journal, 330, 44-62. Xiao, R., Luo, Z., Wei, Z., Luo, S., Spinney, R., Yang, W. and Dionysiou, D. D. (2018). Activation of peroxymonosulfate/persulfate by nanomaterials for sulfate radical-based advanced oxidation technologies. Current Opinion in Chemical Engineering, 19, 51-58. Xing, S., Li, W., Liu, B., Wu, Y. and Gao, Y. (2020). Removal of ciprofloxacin by persulfate activation with CuO: A pH-dependent mechanism. Chemical Engineering Journal, 382. Yang, F., Sheng, B., Wang, Z., Yuan, R., Xue, Y., Wang, X., Liu, Q. and Liu, J. (2019a). An often-overestimated adverse effect of halides in heat/persulfate-based degradation of wastewater contaminants. Environ Int, 130, 104918. Yang, X., Duan, Y., Wang, J., Wang, H., Liu, H. and Sedlak, D. L. (2019b). The Impact of Peroxymonocarbonate (HCO4 (-)) on the Transformation of Organic Contaminants during Hydrogen Peroxide (H2O2) in situ Chemical Oxidation (ISCO). Environ Sci Technol Lett, 6(12), 781-786. Yang, Y., Pignatello, J. J., Ma, J. and Mitch, W. A. (2014). Comparison of halide impacts on the efficiency of contaminant degradation by sulfate and hydroxyl radical-based advanced oxidation processes (AOPs). Environ Sci Technol, 48(4), 2344-2351. Yang, Y., Pignatello, J. J., Ma, J. and Mitch, W. A. (2016). Effect of matrix components on UV/H2O2 and UV/S2O8(2-) advanced oxidation processes for trace organic degradation in reverse osmosis brines from municipal wastewater reuse facilities. Water Res, 89, 192-200. Zhang, T., Chen, Y., Wang, Y., Le Roux, J., Yang, Y. and Croue, J. P. (2014). Efficient peroxydisulfate activation process not relying on sulfate radical generation for water pollutant degradation. Environ Sci Technol, 48(10), 5868-5875. Zhang, W., Zhou, S., Sun, J., Meng, X., Luo, J., Zhou, D. and Crittenden, J. (2018a). Impact of Chloride Ions on UV/H2O2 and UV/Persulfate Advanced Oxidation Processes. Environ Sci Technol, 52(13), 7380-7389. Zhang, Y., Zhang, Q., Dong, Z., Wu, L. and Hong, J. (2018b). Degradation of acetaminophen with ferrous/copperoxide activate persulfate: Synergism of iron and copper. Water Res, 146, 232-243. Zhang, Y., Zhang, Q. and Hong, J. (2017). Sulfate radical degradation of acetaminophen by novel iron–copper bimetallic oxidation catalyzed by persulfate: Mechanism and degradation pathways. Applied Surface Science, 422, 443-451. Zhong, H., Brusseau, M. L., Wang, Y., Yan, N., Quig, L. and Johnson, G. R. (2015). In-situ activation of persulfate by iron filings and degradation of 1,4-dioxane. Water Res, 83, 104-111. Zhou, Y., Xiang, Y., He, Y., Yang, Y., Zhang, J., Luo, L., Peng, H., Dai, C., Zhu, F. and Tang, L. (2018). Applications and factors influencing of the persulfate-based advanced oxidation processes for the remediation of groundwater and soil contaminated with organic compounds. J Hazard Mater, 359, 396-407.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/79580	-
dc.description.abstract	"地下水污染整治一直以來都是維持永續水資源的重要課題，利用現地的方式處理地下水污染是較經濟且對環境較友善的方法。透水性反應牆（permeable reactive barrier, PRB）和現地化學氧化 (In-situ chemical oxidation, ISCO)為現地處理地下水污染的方法。本研究使用氧化銅(CuO)作為透水性反應牆之反應介質，結合過二硫酸鹽作為氧化劑，以現地透水性反應牆化學氧化方式評估在固定流量條件下，2,4-二氯酚、2,4,6-三氯酚及五氯酚的降解效率，並探討不同水質參數包含氯離子、硝酸根、硫酸根、碳酸氫根及腐植酸對五氯酚去除率的影響。追蹤劑實驗結果顯示，架設的實驗系統為重力流，在定流量的條件下（4.8 mL/min），整體水利停留時間為60-75分鐘，而流經CuO透水性反應牆的時間約為10分鐘。三種氯酚類目標污染物在去離子水為基質下的去除率皆可達到99%以上，在含有各種離子的水質條件下，去除效率則有以下的趨勢：2,4,6-三氯酚 > 2,4-二氯酚 > 五氯酚。針對五氯酚在不同水質參數下的降解，實驗結果顯示氯離子和硝酸根對去除效率沒有太大影響，當硫酸根及碳酸氫根濃度分別提高至1.04 mM及10 mM，其去除率仍維持在約90%，較高濃度的腐植酸( 5 mg C/L）則使五氯酚的去除率從96%降至68％，結果顯示腐植酸可能會覆蓋在氧化銅的表面上並有消耗自由基的作用，進而影響五氯酚的降解。"	zh_TW
dc.description.provenance	Made available in DSpace on 2022-11-23T09:04:16Z (GMT). No. of bitstreams: 1 U0001-1509202118313800.pdf: 6435215 bytes, checksum: d00bbdf75d71632e0ee62ae1d8cd9c7e (MD5) Previous issue date: 2021	en
dc.description.tableofcontents	Content 摘要 I Abstract II Content IV List of Figures VII List of Tables X Chapter 1 Introduction 1 1.1 Background 1 1.2 Research objectives 3 Chapter 2 Literature Reviews 4 2.1 In situ chemical oxidation (ISCO) 4 2.2 Permeable reactive barrier (PRB) 4 2.3 Persulfate-based advanced oxidation processes 6 2.4 Influences of water matrixes on the performance of persulfate technologies 9 Chapter 3 Materials and Methods 11 3.1 Research framework 11 3.2 Chemicals and reagents 12 3.3 Characterization of copper oxide 12 3.4 Permeable reactive barrier (PRB) module 13 3.5 Chlorophenol degradation experiments 14 3.6 Analytical methods 15 Chapter 4 Results Discussion 17 4.1 Characterization of CuO and hydraulic properties of PRB module 17 4.2 Removal of chlorophenols by PDS activated by CuO-PRB 20 4.2.1 Removal of chlorophenols by PDS activated by CuO-PRB in DI water 20 4.2.2 Removal of chlorophenols by PDS activated by CuO-PRB in water containing various ions 30 4.3 Influences of water matrixes on PCP removal by PDS activated by CuO-PRB 33 4.3.1 Influences of nitrate on PCP removal 33 4.3.2 Influences of chloride on PCP removal 36 4.3.3 Influences of sulfate on PCP removal 39 4.3.4 Influences of bicarbonate on PCP removal 41 4.3.5 Influences of humic acid on PCP removal 43 Chapter 5 Conclusions and Recommendations 46 5.1 Conclusions 46 5.2 Recommendations 47 Reference 49 Appendix 60
dc.language.iso	en
dc.title	在不同水質參數下利用氧化銅活化過二硫酸鹽降解氯酚類有機污染物：透水性反應牆模組試驗	zh_TW
dc.title	Degradation of Chlorophenols under Different Water Matrixes by CuO-Activated Peroxydisulfate in Permeable Reactive Barrier Module	en
dc.date.schoolyear	109-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	蔣本基(Hsin-Tsai Liu),潘述元(Chih-Yang Tseng)
dc.subject.keyword	透水性反應牆,現地化學氧化,氧化銅,過二硫酸鹽,氯酚,	zh_TW
dc.subject.keyword	permeable reactive barrier,in-situ chemical oxidation,CuO,peroxydisulfate,chlorophenols,	en
dc.relation.page	66
dc.identifier.doi	10.6342/NTU202103198
dc.rights.note	同意授權(全球公開)
dc.date.accepted	2021-09-17
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	環境工程學研究所	zh_TW
顯示於系所單位：	環境工程學研究所

文件中的檔案：

檔案	大小	格式
U0001-1509202118313800.pdf	6.28 MB	Adobe PDF	檢視/開啟

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。