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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 林郁真(Yu-Chen Lin) | |
dc.contributor.author | Kuan-Yu Chen | en |
dc.contributor.author | 陳冠宇 | zh_TW |
dc.date.accessioned | 2021-06-17T07:09:48Z | - |
dc.date.available | 2024-08-12 | |
dc.date.copyright | 2019-08-12 | |
dc.date.issued | 2019 | |
dc.date.submitted | 2019-07-22 | |
dc.identifier.citation | Akbal, F., Nur Onar, A.J.E.M. and Assessment (2003) Photocatalytic Degradation of Phenol. Environmental Monitoring and Assessment 83(3), 295-302.
Araña, J., Doña Rodríguez, J., Rendón, E.D., Garriga i Cabo, C., González Díaz, O., Melián, J., Pérez-Peña, J., Colón, G. and Navı́o, J.A. (2003a) TiO2 activation by using activated carbon as a support: Part I. Surface characterisation and decantability study. Applied Catalysis B: Environmental 44, 161-172. Araña, J., Doña-Rodrı́guez, J.M., Tello Rendón, E., Garriga i Cabo, C., González-Dı́az, O., Herrera-Melián, J.A., Pérez-Peña, J., Colón, G. and Navı́o, J.A. (2003b) TiO2 activation by using activated carbon as a support: Part II. Photoreactivity and FTIR study. Applied Catalysis B: Environmental 44(2), 153-160. Arunkumar, T., Jayaprakash, R., Denkenberger, D., Ahsan, A., Okundamiya, M.S., kumar, S., Tanaka, H. and Aybar, H.Ş. (2012) An experimental study on a hemispherical solar still. Desalination 286, 342-348. Chiou, C.-H., Wu, C.-Y. and Juang, R.-S. (2008) Influence of operating parameters on photocatalytic degradation of phenol in UV/TiO2 process. Chemical Engineering Journal 139(2), 322-329. Dao, V.-D. and Choi, H.-S. (2018) Carbon-Based Sunlight Absorbers in Solar-Driven Steam Generation Devices. Global Challenges 2(2), 1700094. Gao, M., Zhu, L., Peh, C.K., Ho, G.W.J.E. and Science, E. (2019) Solar absorber material and system designs for photothermal water vaporization towards clean water and energy production. Energy & Environmental Science. Gar Alalm, M., Tawfik, A. and Ookawara, S. (2014) Solar photocatalytic degradation of phenol by TiO2 /AC prepared by temperature impregnation method. Desalination and Water Treatment 57. Ghasemi, H., Ni, G., Marconnet, A.M., Loomis, J., Yerci, S., Miljkovic, N. and Chen, G. (2014) Solar steam generation by heat localization. Nature Communications 5, 4449. Hao, D., Yang, Y., Xu, B. and Cai, Z. (2018) Efficient Solar Water Vapor Generation Enabled by Water-Absorbing Polypyrrole Coated Cotton Fabric with Enhanced Heat Localization. Applied Thermal Engineering 141. Hua, Z., Li, B., Li, L., Yin, X., Chen, K. and Wang, W. (2017) Designing a Novel Photothermal Material of Hierarchical Microstructured Copper Phosphate for Solar Evaporation Enhancement. The Journal of Physical Chemistry C 121(1), 60-69. Huo, B., Jiang, D., Cao, X., Liang, H., Liu, Z., Li, C. and Liu, J. (2018) N-doped graphene /carbon hybrid aerogels for efficient solar steam generation. Carbon 142. Ismail, B.I. (2009) Design and performance of a transportable hemispherical solar still. Renewable Energy 34(1), 145-150. Iurascu, B., Siminiceanu, I., Vione, D., Vicente, M.A. and Gil, A. (2009) Phenol degradation in water through a heterogeneous photo-Fenton process catalyzed by Fe-treated laponite. Water Research 43(5), 1313-1322. Jamil, T.S., Ghaly, M.Y., Fathy, N.A., Abd el-halim, T.A. and Österlund, L. (2012) Enhancement of TiO2 behavior on photocatalytic oxidation of MO dye using TiO2/AC under visible irradiation and sunlight radiation. Separation and Purification Technology 98, 270-279. Kannan, S., Dubey, A. and Knozinger, H. (2005) Synthesis and characterization of CuMgAl ternary hydrotalcites as catalysts for the hydroxylation of phenol. Journal of Catalysis 231(2), 381-392. Kim, K., Yu, S., An, C., Kim, S.-W. and Jang, J.-H. (2018) Mesoporous Three-Dimensional Graphene Networks for Highly Efficient Solar Desalination under 1 sun Illumination. ACS Applied Materials & Interfaces 10(18), 15602-15608. Li, J., Du, M., Lv, G., Zhou, L., Li, X., Bertoluzzi, L., Liu, C., Zhu, S. and Zhu, J. (2018) Interfacial Solar Steam Generation Enables Fast-Responsive, Energy-Efficient, and Low-Cost Off-Grid Sterilization. Advanced Materials 30(49), 1805159. Li, W., Li, Z., Bertelsmann, K. and Fan, D.E. (2019) Portable Low-Pressure Solar Steaming-Collection Unisystem with Polypyrrole Origamis. Advanced Materials 0(0), 1900720. Li, X., Xu, W., Tang, M., Zhou, L., Zhu, B., Zhu, S. and Zhu, J. (2016) Graphene oxide-based efficient and scalable solar desalination under one sun with a confined 2D water path. Proceedings of the National Academy of Sciences 113(49), 13953. Liu, P.-F., Miao, L., Deng, Z., Zhou, J., Su, H., Sun, L., Tanemura, S., Cao, W., Jiang, F. and Zhao, L. (2018a) A mimetic transpiration system for record high conversion efficiency in solar steam generator under one-sun. Materials Today Energy 8, 166-173. Liu, S., Huang, C.-L., Luo, X. and Rao, Z. (2018b) High-Performance Solar Steam Generation of a Paper-Based Carbon Particle System. Applied Thermal Engineering 142. Liu, X., Cheng, H., Guo, Z., Zhan, Q., Qian, J. and Wang, X. (2018c) Bifunctional, Moth-Eye-Like Nanostructured Black Titania Nanocomposites for Solar-Driven Clean Water Generation. ACS Applied Materials & Interfaces 10(46), 39661-39669. Liu, Y., Yu, S., Feng, R., Bernard, A., Liu, Y., Zhang, Y., Duan, H., Shang, W., Tao, P., Song, C. and Deng, T. (2015) A Bioinspired, Reusable, Paper-Based System for High-Performance Large-Scale Evaporation. Advanced Materials 27(17), 2768-2774. Lou, J., Liu, Y., Wang, Z., Zhao, D., Song, C., Wu, J., Dasgupta, N., Zhang, W., Zhang, D., Tao, P., Shang, W. and Deng, T. (2016) Bioinspired Multifunctional Paper-Based rGO Composites for Solar-Driven Clean Water Generation. ACS Applied Materials & Interfaces 8(23), 14628-14636. Michaels, A.J.D. (1990) Membranes, membrane processes, and their applications: needs, unsolved problems, and challenges of the 1990's. Desalination 77, 5-34. Ming, X., Guo, A., Wang, G. and Wang, X. (2018) Two-dimensional defective tungsten oxide nanosheets as high performance photo-absorbers for efficient solar steam generation. Solar Energy Materials and Solar Cells 185. Phadatare, M.K. and Verma, S.K. (2007) Influence of water depth on internal heat and mass transfer in a plastic solar still. Desalination 217(1), 267-275. Shanmugan, S., Rajamohan, P. and Mutharasu, D. (2008) Performance study on an acrylic mirror boosted solar distillation unit utilizing seawater. Desalination 230(1), 281-287. Shi, J.-W., Cui, H.-J., Chen, J.-W., Fu, M.-L., Xu, B., Luo, H.-Y. and Ye, Z.-L. (2012) TiO2/activated carbon fibers photocatalyst: Effects of coating procedures on the microstructure, adhesion property, and photocatalytic ability. Journal of Colloid and Interface Science 388(1), 201-208. Shi, L., Shi, Y., Zhuo, S., Zhang, C., Aldrees, Y., Aleid, S. and Wang, P. (2019) Multi-functional 3D honeycomb ceramic plate for clean water production by heterogeneous photo-Fenton reaction and solar-driven water evaporation. Nano Energy 60. Shi, L., Wang, Y., Zhang, L. and Wang, P. (2017) Rational design of a bi-layered reduced graphene oxide film on polystyrene foam for solar-driven interfacial water evaporation. Journal of Materials Chemistry A 5(31), 16212-16219. Taamneh, Y. and Taamneh, M. (2012) Performance of pyramid-shaped solar still: Experimental study. Desalination 291, 65–68. Wang, G., Fu, Y., Guo, A., Mei, T., Wang, J., Li, J. and Wang, X. (2017a) Reduced Graphene Oxide–Polyurethane Nanocomposite Foam as a Reusable Photoreceiver for Efficient Solar Steam Generation. Chemistry of Materials 29(13), 5629-5635. Wang, J., Li, Y., Deng, L., Wei, N., Weng, Y., Dong, S., Qi, D., Qiu, J., Chen, X. and Wu, T. (2017b) High-Performance Photothermal Conversion of Narrow-Bandgap Ti2O3 Nanoparticles. Advanced Materials 29(3), 1603730. Wang, X., He, Y., Liu, X., Cheng, G. and Zhu, J. (2017c) Solar steam generation through bio-inspired interface heating of broadband-absorbing plasmonic membranes. Applied Energy 195, 414-425. Wang, Y., Wang, C., Song, X., Megarajan, S.K. and Jiang, H. (2018) A facile nanocomposite strategy to fabricate a rGO–MWCNT photothermal layer for efficient water evaporation. Journal of Materials Chemistry A 6(3), 963-971. WHO (2011) Guidelines for drinking-water quality, World Health Organization. Xu, Y., Ma, J., Liu, D., Xu, H., Cui, F. and Wang, W.J.C.E.J. (2019) Origami system for efficient solar driven distillation in emergency water supply. Chemical Engineering Journal 356, 869-876. Yang, P., Liu, K., Chen, Q., Li, J., Duan, J., Xue, G., Xu, Z., Xie, W. and Zhou, J. (2017) Solar-driven simultaneous steam production and electricity generation from salinity. Energy & Environmental Science 10(9), 1923-1927. Yin, Z., Wang, H., Jian, M., Li, Y., Xia, K., Zhang, M., Wang, C., Wang, Q., Ma, M., Zheng, Q.-s. and Zhang, Y. (2017) Extremely Black Vertically Aligned Carbon Nanotube Arrays for Solar Steam Generation. ACS Applied Materials & Interfaces 9(34), 28596-28603. Zhao, R., Xu, J., Tao, P., Shi, F., Yu, F., Zeng, X., Song, C., Wu, J., Shang, W. and Deng, T. (2018) Clean water generation with switchable dispersion of multifunctional Fe3O4-reduced graphene oxide particles. Progress in Natural Science: Materials International 28(4), 422-429. Zhu, L., Gao, M., Peh, C.K.N., Wang, X. and Ho, G.W. (2018) Self-Contained Monolithic Carbon Sponges for Solar-Driven Interfacial Water Evaporation Distillation and Electricity Generation. Advanced Energy Materials 8(16), 1702149. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/72903 | - |
dc.description.abstract | 由於人類社會的快速發展,全球氣候變遷和人口增長導致了水資源在質跟量方面的衰退,替代性水資源的開發正如火如荼的展開;然而,現行的海水淡化或是水回收技術需要耗費大量能源,而這對一些缺乏能源基礎建設的地區是相當大的挑戰,因此發展低能耗、高產量的潔淨水生產技術是勢在必行的。利用浮於界面的光熱轉換層促進太陽能蒸餾水為一具發展性的潔淨水生產技術。在本研究中,我們製作了一具雙重功能的界面蒸發裝置;此裝置除了擁有高的蒸氣產生效率之外,更能夠有效防止揮發性有機物(酚)被一同蒸發進入乾淨的蒸餾水。我們以混合了二氧化鈦光觸媒的活性碳作為光熱轉換層,而以聚乙烯泡棉作為此界面裝置的支撐層。由於活性碳良好的吸光度,再加上聚乙烯泡棉除了賦予裝置浮於界面的能力外,更透過熱區域化的方式進一步提升裝置的蒸氣產生表現,其蒸氣產生速率分別為無裝置時和傳統蒸發系統(沉浸於水溶液底部的二氧化鈦活性碳)的3倍以及1.7倍。除了界面蒸發優異的蒸氣產生表現外,本研究亦證明界面蒸發系統不易受水中懸浮固體的影響,其原因為透過於界面吸光,能夠避免因懸浮固體所導致的光散射而造成入射光強度減少的問題。本實驗中也利用合成鹽水(3.5% (w/v)的氯化鈉溶液)進行潔淨水生產的展示;透過界面蒸發,在蒸餾水中僅能發現低濃度的氯離子,且相較於無蒸發裝置的系統,界面蒸發系統有更高的蒸餾水產量。除此之外,此界面蒸發裝置能夠有效避免水中的酚在太陽能蒸餾過程中與水一起蒸發並收集至蒸餾水中;主要原因是由於酚在通過界面蒸發裝置時將受裝置上的活性碳吸附及二氧化鈦光催化反應而使其降解。應用界面蒸發在太陽能蒸餾程序,不僅能有更高的蒸餾水產量,其產生的蒸餾水也有更好的水質,顯示界面蒸發輔助太陽能蒸餾作為潔淨水生產程序的潛力。 | zh_TW |
dc.description.abstract | Due to the rapid development of human society, freshwater resources have degraded in both quantity and quality. The exploitation of alternative water resources, such as seawater and wastewater is imperative. However, current techniques for desalination and water reuse have the disadvantage of high energy consumption, which could inhibit development in areas lacking energy infrastructures. Therefore, developing clean water generation techniques with low energy consumption and high efficiency is necessary. Interfacial solar distillation systems assisted by floating photothermal layers are a promising method for clean water generation. In this study, a bifunctional interfacial evaporation device with high steam generation efficiency and rejection ability of phenol in distilled water was established. Activated carbon (AC) blended with commercially available TiO2 (AC-P25) served as the photothermal layer, and polyethylene foam (PE foam) was used as the supporting layer. The excellent optical absorbance of AC and the heat localization effect caused by PE foam promoted the steam generation performance by increasing the evaporation rate 3 and 1.7 times, compared with the water-only and the conventional evaporation (i.e., submerged AC-P25) systems, respectively. In addition to the superior steam generation performance, interfacial evaporation was proven to be less affected by suspended solids in water by reducing the influence of the light scattering effect. Clean water generation was demonstrated using synthetic saline water (3.5% (w/v) NaCl(aq)), and good salt rejection and high water productivity were achieved through interfacial evaporation. Additionally, phenol enrichment during solar distillation was successfully prevented with the use of AC-P25/foam through adsorption and photocatalytic degradation. The high distilled water productivity and good distilled water quality indicated the potential of interfacial solar distillation in clean water generation. | en |
dc.description.provenance | Made available in DSpace on 2021-06-17T07:09:48Z (GMT). No. of bitstreams: 1 ntu-108-R06541106-1.pdf: 2387571 bytes, checksum: 911818c3107b6b90da7024f3d6784573 (MD5) Previous issue date: 2019 | en |
dc.description.tableofcontents | 口試委員審定書 I
致謝 II 摘要 IV Abstract V Contents VII List of Figures IX List of Tables X Chapter 1 Introduction 1 1.1 Background 1 1.2 Objective 2 1.3 Research framework 4 Chapter 2 Literature Review 6 2.1 Conventional solar distillation 6 2.2 Steam generation through interfacial evaporation 8 2.3 Photothermal material with photocatalytic ability 12 2.4 Phenol removal using TiO2-activated carbon composite 14 Chapter 3 Materials and Methods 16 3.1 Materials 16 3.2 Construction of the interfacial evaporation devices 17 3.3 Characterization 19 3.4 Steam generation tests 19 3.5 Effect of suspended solids on steam generation 20 3.6 Phenol removal test using AC-P25 20 3.7 Demonstration of clean water generation 21 Chapter 4 Results and Discussion 25 4.1 UV-Vis absorption spectra of the different photothermal layers 25 4.2 Steam generation performances 26 4.3 Effect of suspended solids on steam generation 33 4.4 Removal of phenol using AC-P25 35 4.5 Generation of clean water using AC-P25/foam 37 Chapter 5 Conclusions and Suggestions 41 5.1 Conclusions 41 5.2 Suggestions for future work 43 References 46 | |
dc.language.iso | en | |
dc.title | 界面型太陽能蒸餾系統應用於潔淨水生產之研究 | zh_TW |
dc.title | Clean Water Generation Through Interfacial Solar Distillation | en |
dc.type | Thesis | |
dc.date.schoolyear | 107-2 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 林逸彬(Yi-Pin Lin),康佩群(Pui-Kwan Hong) | |
dc.subject.keyword | 光熱轉換,光催化,界面蒸發,太陽能蒸餾, | zh_TW |
dc.subject.keyword | photothermal conversion,photocatalysis,interfacial evaporation,solar distillation, | en |
dc.relation.page | 49 | |
dc.identifier.doi | 10.6342/NTU201901704 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2019-07-23 | |
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 |
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