合成及設計新型Z-scheme異質結ferrite/UiO66-NH2光觸媒與固態電子介質用於水中染料光降解

Yen-Ju Lai; 賴妍如

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/81820

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	李篤中(Duu-Jong Lee)
dc.contributor.author	Yen-Ju Lai	en
dc.contributor.author	賴妍如	zh_TW
dc.date.accessioned	2022-11-25T03:04:21Z	-
dc.date.available	2024-08-02
dc.date.copyright	2021-08-20
dc.date.issued	2021
dc.date.submitted	2021-08-03
dc.identifier.citation	[1] Skromme, B. J., G. K. Sujan, Semiconductor heterojunctions. Reference Module in Materials Science and Materials Engineering, 2018. [2] Chen, C., J. Zhou, J. Geng, R. Bao, Z. Wang, J. Xia, H. Li, Perovskite LaNiO3/TiO2 step-scheme heterojunction with enhanced photocatalytic activity. Applied Surface Science, 2020.503:144287. [3] Garcia-Muñoz, P., C. Lefevre, D. Robert, N. Keller, Ti-substituted LaFeO3 perovskite as photoassisted CWPO catalyst for water treatment. Applied Catalysis B: Environmental, 2019.248:120-128. [4] Zhang, X., J. Wang, X. X. Dong, Y. K. Lv, Functionalized metal-organic frameworks for photocatalytic degradation of organic pollutants in environment. Chemosphere, 2020.242:125144. [5] Nahyoon, N. A., L. Liu, W. Saleem, S. A. Nahyoon, K. Rabé, Efficient photocatalytic treatment of sugar mill wastewater with 2% Ag3PO4/Fe/GTiP nanocomposite. Arabian Journal of Chemistry, 2020.13:3624-3632. [6] Lee, C. C., C. I. Chen, Y. T. Liao, K. C. W. Wu, C. C. Chueh, Enhancing efficiency and stability of photovoltaic cells by using perovskite/Zr-MOF heterojunction including bilayer and hybrid structures. Advanced Science, 2019.6:1801715. [7] Luo, H., Z. Zeng, G. Zeng, C. Zhang, R. Xiao, D. Huang, C. Lai, M. Cheng, W. Wang, W. Xiong, Y. Yang, L. Qin, C. Zhou, H. Wang, Y. Zhou, S. Tian, Recent progress on metal-organic frameworks based- and derived-photocatalysts for water splitting. Chemical Engineering Journal, 2020.383:123196. [8] Jiang, Y., J. F. Liao, H. Y. Chen, H. H. Zhang, J. Y. Li, X. D. Wang, D. B. Kuang, All-solid-state Z-Scheme α-Fe2O3/Amine-RGO/CsPbBr3 hybrids for visible-light-driven photocatalytic CO2 reduction. Chemistry, 2020.6:766-780. [9] Zhang, K., C. Ding, Y. She, Z. Wu, C. Zhao, B. Pan, L. Zhang, W. Zhou, Q. Fan, CuFe2O4/MoS2 Mixed-Dimensional Heterostructures with Improved Gas Sensing Response. Nanoscale Research Letters, 2020.15:1-7. [10] Lin, X., F. Rong, D. Fu, C. Yuan, Enhanced photocatalytic activity of fluorine doped TiO2 by loaded with Ag for degradation of organic pollutants. Powder Technology, 2012.219:173-178. [11] Aliaga, J., N. Cifuentes, G. González, C. Sotomayor-Torres, E. Benavente, Enhancement photocatalytic activity of the heterojunction of two-dimensional hybrid semiconductors ZnO/V2O5. Catalysts, 2018.8:374. [12] Cao, X. L., L. G. Zhang, T. X. Chen, C. Feng, Z. C. Liu, Y. Qi, W. Wang, J. D. Wang, MOF based sheet-assembled flowers CdS-MoS2 composite for enhanced visible-light hydrogen production. Applied Surface Science, 2020.511:145355. [13] Su, Y., X. Yu, X. Fu, Q. Zhu, L. Liu, Y. Zhu, Y. Zhang, Embedding Ag nanoparticles to construct BiOI/Ag/PANI with enhanced photoelectrocatalytic activity: a demonstration of the switch from type-II to Z-scheme. Electrochimica Acta, 2020.344:136144. [14] Wang, Y., P. Zhang, T. C. Zhang, G. Xiang, X. Wang, S. Pehkonen, S. Yuan, A magnetic γ-Fe2O3@PANI@TiO2 core–shell nanocomposite for arsenic removal via a coupled visible-light-induced photocatalytic oxidation–adsorption process. Nanoscale Advances, 2020.2:2018-2024. [15] Budi, I. S., S. J. Santosa, E. S. Kunarti, Polyaniline (Pani)-sensitized Fe3O4/SiO2/TiO2 nanocomposites as photocatalyst for the reduction of Au(iii) ions. Rasayan Journal of Chemistry, 2020.13:202-209. [16] Li, X., D. Wei, L. Ye, Z. Li, Fabrication of Cu2O-RGO/BiVO4 nanocomposite for simultaneous photocatalytic CO2 reduction and benzyl alcohol oxidation under visible light. Inorganic Chemistry Communications, 2019.104:171-177. [17] Bhowmick, G. D., I. Chakraborty, M. M. Ghangrekar, A. Mitra, TiO2/Activated carbon photo cathode catalyst exposed to ultraviolet radiation to enhance the efficacy of integrated microbial fuel cell-membrane bioreactor. Bioresource Technology Reports, 2019.7:100303. [18] Ji, R., M. Zhang, W. Ma, Z. Zhu, C. Ma, P. Huo, Y. Yan, Y. liu, C. Li, Heterojunction photocatalyst fabricated by deposition Co3O4 nanoparticles on MoS2 nanosheets with enhancing photocatalytic performance and mechanism insight. Journal of the Taiwan Institute of Chemical Engineers, 2019.97:158-169. [19] Cui, K., X. Wang, M. Tai, B. Gao, B. Su, Facile synthesis of intercalated Z-scheme Bi2O4/g-C3N4 composite photocatalysts for effective removal of 2-Mercaptobenzothiazole: degradation pathways and mechanism. Journal of the Taiwan Institute of Chemical Engineers, 2020.111:212-221. [20] Balu, S., S. Velmurugan, S. Palanisamy, S. W. Chen, V. Velusamy, T. C. K. Yang, E. S. I. El-Shafey, Synthesis of α-Fe2O3 decorated g-C3N4/ZnO ternary Z-scheme photocatalyst for degradation of tartrazine dye in aqueous media. Journal of the Taiwan Institute of Chemical Engineers, 2019.99:258-267. [21] Hitam, C. N. C., A. A. Jalil, A review on exploration of Fe2O3 photocatalyst towards degradation of dyes and organic contaminants. Journal of Environmental Management, 2020.258:110050. [22] Bao, Y., K. Chen, A novel Z-scheme visible light driven Cu2O/Cu/g-C3N4 photocatalyst using metallic copper as a charge transfer mediator. Molecular Catalysis, 2017.432:187-195. [23] He, J., D. W. Shao, L. C. Zheng, L. J. Zheng, D. Q. Feng, J. P. Xu, X. H. Zhang, W. C. Wang, W. H. Wang, F. Lu, H. Dong, Y. H. Cheng, H. Liu, R. K. Zheng, Construction of Z-scheme Cu2O/Cu/AgBr/Ag photocatalyst with enhanced photocatalytic activity and stability under visible light. Applied Catalysis B: Environmental, 2017.203:917-926. [24] Li, Q., M. Lu, W. Wang, W. Zhao, G. Chen, H. Shi, Fabrication of 2D/2D g-C3N4/Au/Bi2WO6 Z-scheme photocatalyst with enhanced visible-light-driven photocatalytic activity. Applied Surface Science, 2020.508:144182. [25] Lai, Y.-J., D.-J. Lee, Solid mediator Z-scheme heterojunction photocatalysis for pollutant oxidation in water: Principles and synthesis perspectives. Journal of the Taiwan Institute of Chemical Engineers, 2021. [26] Wu, H. W., A. Emadi, G. de Graaf, J. Leijtens, R. F. Wolffenbuttel, Design and Fabrication of an Albedo Insensitive Analog Sun Sensor. Procedia Engineering, 2011.25:527-530. [27] Askari, N., M. Beheshti, D. Mowla, M. Farhadian, Synthesis of CuWO4/Bi2S3 Z-scheme heterojunction with enhanced cephalexin photodegradation. Journal of Photochemistry and Photobiology A: Chemistry, 2020.394:112463. [28] Chen, C., J. Zhou, J. Geng, R. Bao, Z. Wang, J. Xia, H. Li, Perovskite LaNiO3/TiO2 step-scheme heterojunction with enhanced photocatalytic activity. Applied Surface Science, 2020.503:144287:144287. [29] Zhang, X., J. Wang, X. X. Dong, Y. K. Lv, Functionalized metal-organic frameworks for photocatalytic degradation of organic pollutants in environment. Chemosphere, 2020.242:125144:Unsp 125144. [30] Nahyoon, N. A., L. Liu, W. Saleem, S. A. Nahyoon, K. Rabé, Efficient photocatalytic treatment of sugar mill wastewater with 2%Ag3PO4/Fe/GTiP nanocomposite. Arabian Journal of Chemistry, 2020.13:3624-3632. [31] Lee, C. C., C. I. Chen, Y. T. Liao, K. C. W. Wu, C. C. Chueh, Enhancing efficiency and stability of photovoltaic cells by using Perovskite/Zr-MOF heterojunction including bilayer and hybrid structures. Advanced Science, 2019.6:1801715:1801715. [32] Luo, H., Z. Zeng, G. Zeng, C. Zhang, R. Xiao, D. Huang, C. Lai, M. Cheng, W. Wang, W. Xiong, Y. Yang, L. Qin, C. Zhou, H. Wang, Y. Zhou, S. Tian, Recent progress on metal-organic frameworks based- and derived-photocatalysts for water splitting. Chemical Engineering Journal, 2020.383:123196:123196. [33] Jiang, Y., J.-F. Liao, H.-Y. Chen, H.-H. Zhang, J.-Y. Li, X.-D. Wang, D.-B. Kuang, All-solid-state Z-Scheme α-Fe2O3/Amine-RGO/CsPbBr3 hybrids for visible-light-driven photocatalytic CO2 reduction. Chemistry, 2020.6:766-780. [34] Zhang, K., C. Ding, Y. She, Z. Wu, C. Zhao, B. Pan, L. Zhang, W. Zhou, Q. Fan, CuFe2O4/MoS2 Mixed-Dimensional Heterostructures with Improved Gas Sensing Response. Nanoscale Research Letters, 2020.15:32:32. [35] Stelo, F., N. Kublik, S. Ullah, H. Wender, Recent advances in Bi2MoO6 based Z-scheme heterojunctions for photocatalytic degradation of pollutants. Journal of Alloys and Compounds, 2020.829:154591. [36] Xue, W., D. Huang, X. Wen, S. Chen, M. Cheng, R. Deng, B. Li, Y. Yang, X. Liu, Silver-based semiconductor Z-scheme photocatalytic systems for environmental purification. Journal of Hazardous Materials, 2020.390:122128. [37] Jiang, W., X. Zong, L. An, S. Hua, X. Miao, S. Luan, Y. Wen, F. F. Tao, Z. Sun, Consciously constructing heterojunction or direct Z-scheme photocatalysts by regulating electron flow direction. ACS Catalysis, 2018.8:2209-2217. [38] Wan, S. P., M. Ou, Q. Zhong, X. M. Wang, Perovskite-type CsPbBr3 quantum dots/UiO-66(NH2) nanojunction as efficient visible-light-driven photocatalyst for CO2 reduction. Chemical Engineering Journal, 2019.358:1287-1295. [39] Li, L., X. Yu, L. Xu, Y. Zhao, Fabrication of a novel type visible-light-driven heterojunction photocatalyst: metal-porphyrinic metal organic framework coupled with PW12/TiO2. Chemical Engineering Journal, 2020.386:123955. [40] Kshirsagar, A. S., P. K. Khanna, CuSbSe2/TiO2: novel type-II heterojunction nano-photocatalyst. Materials Chemistry Frontiers, 2019.3:437-449. [41] Heidari, S., M. Haghighi, M. Shabani, Sono-photodeposition of Ag over sono-fabricated mesoporous Bi2Sn2O7-two dimensional carbon nitride: type-II plasmonic nano-heterojunction with simulated sunlight-driven elimination of drug. Chemical Engineering Journal, 2020.389:123418. [42] Subudhi, S., L. Paramanik, S. Sultana, S. Mansingh, P. Mohapatra, K. Parida, A type-II interband alignment heterojunction architecture of cobalt titanate integrated UiO-66-NH2: a visible light mediated photocatalytic approach directed towards Norfloxacin degradation and green energy (Hydrogen) evolution. Journal of Colloid and Interface Science, 2020.568:89-105. [43] Xu, Q., L. Zhang, J. Yu, S. Wageh, A. A. Al-Ghamdi, M. Jaroniec, Direct Z-scheme photocatalysts: principles, synthesis, and applications. Materials Today, 2018.21:1042-1063. [44] Tan, H. L., F. F. Abdi, Y. H. Ng, Heterogeneous photocatalysts: an overview of classic and modern approaches for optical, electronic, and charge dynamics evaluation. Chemical Society Reviews, 2019.48:1255-1271. [45] Balu, S., S. Velmurugan, S. Palanisamy, S.-W. Chen, V. Velusamy, T. C. K. Yang, E.-S. I. El-Shafey, Synthesis of α-Fe2O3 decorated g-C3N4/ZnO ternary Z-scheme photocatalyst for degradation of tartrazine dye in aqueous media. Journal of the Taiwan Institute of Chemical Engineers, 2019.99:258-267. [46] Hitam, C. N. C., A. A. Jalil, A review on exploration of Fe2O3 photocatalyst towards degradation of dyes and organic contaminants. Journal of Environmental Management, 2020.258:110050:110050. [47] Aliaga, J., N. Cifuentes, G. González, C. Sotomayor-Torres, E. Benavente, Enhancement photocatalytic activity of the heterojunction of two-dimensional hybrid semiconductors ZnO/V2O5. Catalysts, 2018.8:374. [48] Su, Y., X. Yu, X. Fu, Q. Zhu, L. Liu, Y. Zhu, Y. Zhang, Embedding Ag nanoparticles to construct BiOI/Ag/PANI with enhanced photoelectrocatalytic activity: A demonstration of the switch from type-II to Z-scheme. Electrochimica Acta, 2020.344:136144:136144. [49] Liu, X. W., W. Q. Li, R. Hu, Y. Wei, W. Y. Yun, P. Nian, J. W. Feng, A. Y. Zhang, Synergistic degradation of acid orange 7 dye by using non-thermal plasma and g-C3N4/TiO2: Performance, degradation pathways and catalytic mechanism. Chemosphere, 2020.249:11:126093. [50] Rasheed, T., M. Bilal, H. M. N. Iqbal, H. Hu, X. Zhang, Reaction mechanism and degradation pathway of rhodamine 6G by photocatalytic treatment. Water, Air, Soil Pollution, 2017.228:1-10. [51] Musteret, C.-P., C. Teodosiu, Removal of persistent organic pollutants from textile wastewater by membrane processes. Environmental Engineering and Management Journal, 2007.6:175-187. [52] Kishor, R., D. Purchase, G. D. Saratale, R. G. Saratale, L. F. R. Ferreira, M. Bilal, R. Chandra, R. N. Bharagava, Ecotoxicological and health concerns of persistent coloring pollutants of textile industry wastewater and treatment approaches for environmental safety. Journal of Environmental Chemical Engineering, 2021.9:105012. [53] Zhang, Q., L. Jiang, J. Wang, Y. Zhu, Y. Pu, W. Dai, Photocatalytic degradation of tetracycline antibiotics using three-dimensional network structure perylene diimide supramolecular organic photocatalyst under visible-light irradiation. Applied Catalysis B: Environmental, 2020.277:119122. [54] Li, Q., M. Lu, W. Wang, W. Zhao, G. Chen, H. Shi, Fabrication of 2D/2D g-C3N4/Au/Bi2WO6 Z-scheme photocatalyst with enhanced visible-light-driven photocatalytic activity. Applied Surface Science, 2020.508:144182. [55] Zhuang, J., Q. Tian, S. Lin, W. Yang, L. Chen, P. Liu, Precursor morphology-controlled formation of perovskites CaTiO3 and their photo-activity for As(III) removal. Applied Catalysis B: Environmental, 2014.156:108-115. [56] Lai, Y. J., D. J. Lee, Pollutant degradation with mediator Z-scheme heterojunction photocatalyst in water: A review. Chemosphere, 2021.282:131059. [57] Zhang, J., Z. Zhang, W. Zhu, X. Meng, Boosted photocatalytic degradation of Rhodamine B pollutants with Z-scheme CdS/AgBr-rGO nanocomposite. Applied Surface Science, 2020.502:144275. [58] Bao, S., Z. Wang, J. Zhang, B. Tian, Facet-heterojunction-based Z‑Scheme BiVO4{010} microplates decorated with AgBr-Ag nanoparticles for the photocatalytic inactivation of bacteria and the decomposition of organic contaminants. ACS Applied Nano Materials, 2020.3:8604-8617. [59] Madkour, M., A. A. Ali, A. Abdel Nazeer, F. Al Sagheer, C. Belver, A novel natural sunlight active photocatalyst of CdS/SWCNT/CeO2 heterostructure: In depth mechanistic insights for the catalyst reactivity and dye mineralization. Applied Surface Science, 2020.499:143988. [60] Mahzoon, S., M. Haghighi, M. Nowee, H. Zeinalzadeh, Sonoprecipitation design of novel efficient all-solid Z-Scheme Cu(OH)2/Cu2O/C3N4 nanophotocatalyst applied in water splitting for H2 production: Synergetic effect of Cu-Based cocatalyst (Cu(OH)2) and electron mediator (Cu). Solar Energy Materials and Solar Cells, 2021.219:110772. [61] Pan, Y., X. Yuan, L. Jiang, H. Wang, H. Yu, J. Zhang, Stable self-assembly AgI/UiO-66(NH2) heterojunction as efficient visiblelight responsive photocatalyst for tetracycline degradation and mechanism insight. Chemical Engineering Journal, 2020.384:123310:123310. [62] Sahoo, D. P., S. Patnaik, K. Parida, Construction of a Z-Scheme dictated WO3-X /Ag/ZnCr LDH synergistically visible light-induced photocatalyst towards tetracycline degradation and H2 evolution. ACS Omega, 2019.4:14721-14741. [63] Cai, Z., L. Huang, X. Quan, Z. Zhao, Y. Shi, G. Li Puma, Acetate production from inorganic carbon (HCO3-) in photo-assisted biocathode microbial electrosynthesis systems using WO3/MoO3/g-C3N4 heterojunctions and Serratia marcescens species. Applied Catalysis B: Environmental, 2020.267:118611. [64] Huo, X., Y. Yang, Q. Niu, Y. Zhu, G. Zeng, C. Lai, H. Yi, M. Li, Z. An, D. Huang, Y. Fu, B. Li, L. Li, M. Zhang, A direct Z-scheme oxygen vacant BWO/oxygen-enriched graphitic carbon nitride polymer heterojunction with enhanced photocatalytic activity. Chemical Engineering Journal, 2021.403:126363. [65] Chen, X. Y., X. L. Xue, X. W. Gong, A novel Z-scheme porous g-C3N4 nanosheet/Ag3PO4 photocatalyst decorated with N-doped CDs for high efficiency removal of antibiotics. Dalton Transactions, 2020.49:5205-5218. [66] Kumar, A., A. Kumari, G. Sharma, B. Du, M. Naushad, F. J. Stadler, Carbon quantum dots and reduced graphene oxide modified self-assembled S@C3N4/B@C3N4 metal-free nano-photocatalyst for high performance degradation of chloramphenicol. Journal of Molecular Liquids, 2020.300:112356:112356. [67] Chen, M. X., Y. Z. Dai, J. Guo, H. T. Yang, D. N. Liu, Y. L. Zhai, Solvothermal synthesis of biochar@ZnFe2O4/BiOBr Z-scheme heterojunction for efficient photocatalytic ciprofloxacin degradation under visible light. Applied Surface Science, 2019.493:1361-1367. [68] Yang, B., J. Zheng, W. Li, R. Wang, D. Li, X. Guo, R. D. Rodriguez, X. Jia, Engineering Z-scheme TiO2-OV-BiOCl via oxygen vacancy for enhanced photocatalytic degradation of imidacloprid. Dalton Transactions, 2020.49:11010-11018. [69] Naimi Joubani, M., M. A. Zanjanchi, S. Sohrabnezhad, The carboxylate magnetic – Zinc based metal-organic framework heterojunction: Fe3O4-COOH@ZIF-8/Ag/Ag3PO4 for plasmon enhanced visible light Z-scheme photocatalysis. Advanced Powder Technology, 2020.31:29-39. [70] Padervand, M., S. Ghasemi, S. Hajiahmadi, C. Wang, K4Nb6O17/Fe3N/α-Fe2O3/C3N4 as an enhanced visible light-driven quaternary photocatalyst for acetamiprid photodegradation, CO2 reduction, and cancer cells treatment. Applied Surface Science, 2021.544:148939. [71] Hu, Z., X. Xie, S. Li, M. Song, G. Liang, J. Zhao, Z. Wang, Rational construct CQDs/BiOCOOH/uCN photocatalyst with excellent photocatalytic performance for degradation of sulfathiazole. Chemical Engineering Journal, 2021.404:126541. [72] Wang, R., G. Qiu, Y. Xiao, X. Tao, W. Peng, B. Li, Optimal construction of WO3·H2O/Pd/CdS ternary Z-scheme photocatalyst with remarkably enhanced performance for oxidative coupling of benzylamines. Journal of Catalysis, 2019.374:378-390. [73] Pan, Y., X. Yuan, L. Jiang, H. Wang, H. Yu, J. Zhang, Stable self-assembly AgI/UiO-66(NH2) heterojunction as efficient visiblelight responsive photocatalyst for tetracycline degradation and mechanism insight. Chemical Engineering Journal, 2020.384:123310. [74] Zhao, W., T. Ding, Y. Wang, M. Wu, W. Jin, Y. Tian, X. Li, Decorating Ag/AgCl on UiO-66-NH2: synergy between Ag plasmons and heterostructure for the realization of efficient visible light photocatalysis. Chinese Journal of Catalysis, 2019.40:1187-1197. [75] Zhang, N., X. Zhang, C. Gan, J. Zhang, Y. Liu, M. Zhou, C. Zhang, Y. Fang, Heterostructural Ag3PO4/UiO-66 composite for highly efficient visible-light photocatalysts with long-term stability. Journal of Photochemistry and Photobiology A: Chemistry, 2019.376:305-315. [76] Li, Z., J. Liu, D. Wang, Y. Gao, J. Shen, Cu2O/Cu/TiO2 nanotube Ohmic heterojunction arrays with enhanced photocatalytic hydrogen production activity. International Journal of Hydrogen Energy, 2012.37:6431-6437. [77] Zuo, S., Y. Chen, W. Liu, C. Yao, X. Li, Z. Li, C. Ni, X. Liu, A facile and novel construction of attapulgite/Cu2O/Cu/g-C3N4 with enhanced photocatalytic activity for antibiotic degradation. Ceramics International, 2017.43:3324-3329. [78] Li, Z., J. Lyu, K. Sun, M. Ge, Construction of magnetic AgBr/Cu/CuFe2O4 Z-scheme photocatalyst with improved photocatalytic performance. Materials Letters, 2018.214:257-260. [79] Wang, S. Q., X. Y. Zhang, X. Y. Dao, X. M. Cheng, W. Y. Sun, Cu2O@Cu@UiO-66-NH2 ternary nanocubes for photocatalytic CO2 reduction. ACS Applied Nano Materials, 2020.3:10437-10445. [80] Ye, E., S. Y. Zhang, S. Liu, M. Y. Han, Disproportionation for growing copper nanowires and their controlled self-assembly facilitated by ligand exchange. Chemistry, 2011.17:3074-3077. [81] Gao, Y., L. Torrente-Murciano, Mechanistic insights of the reduction of gold salts in the Turkevich protocol. Nanoscale, 2020.12:2740-2751. [82] Yao, G. D., Z. B. Huo, F. M. Jin, Direct reduction of copper oxide into copper under hydrothermal conditions. Research on Chemical Intermediates, 2011.37:351-358. [83] Mahzoon, S., M. Haghighi, M. Nowee, H. Zeinalzadeh, Sonoprecipitation design of novel efficient all-solid Z-Scheme Cu(OH)2/Cu2O/C3N4 nanophotocatalyst applied in water splitting for H2 production: synergetic effect of Cu-Based cocatalyst (Cu(OH)2) and electron mediator (Cu). Solar Energy Materials and Solar Cells, 2021.219:110772. [84] Hou, X., L. Wu, L. Gu, G. Xu, H. Du, Y. Yuan, Maximizing the photocatalytic hydrogen evolution of Z-scheme UiO-66-NH2@Au@CdS by aminated-functionalized linkers. Journal of Materials Science: Materials in Electronics, 2019.30:5203-5211. [85] Cao, S. W., J. Fang, M. M. Shahjamali, Z. Wang, Z. Yin, Y. Yang, F. Y. C. Boey, J. Barber, S. C. J. Loo, C. Xue, In situ growth of Au nanoparticles on Fe2O3 nanocrystals for catalytic applications. CrystEngComm, 2012.14:7229-7235. [86] Qin, Y., J. Lu, F. Meng, X. Lin, Y. Feng, Y. Yan, M. Meng, Rationally constructing of a novel 2D/2D WO3/Pt/g-C3N4 Schottky-Ohmic junction towards efficient visible-light-driven photocatalytic hydrogen evolution and mechanism insight. Journal of Colloid and Interface Science, 2020.586:576-587. [87] Sun, Y., Q. Zhu, B. Bai, Y. Li, C. He, Novel all-solid-state Z-scheme SnO2/Pt/In2O3 photocatalyst with boosted photocatalytic performance on water splitting and 2,4-dichlorophenol degradation under visible light. Chemical Engineering Journal, 2020.390:124518. [88] Wang, C., Y. Zhang, X. Sun, Y. Sun, F. Liu, X. Yan, C. Wang, P. Sun, G. Lu, Preparation of Pd/PdO loaded WO3 microspheres for H2S detection. Sensors and Actuators B: Chemical, 2020.321:128629. [89] Majeed, I., U. Manzoor, F. K. Kanodarwala, M. A. Nadeem, E. Hussain, H. Ali, A. Badshah, J. A. Stride, M. A. Nadeem, Pd–Ag decorated g-C3N4 as an efficient photocatalyst for hydrogen production from water under direct solar light irradiation. Catalysis Science Technology, 2018.8:1183-1193. [90] Kefeni, K. K., B. B. Mamba, Photocatalytic application of spinel ferrite nanoparticles and nanocomposites in wastewater treatment: review. Sustainable Materials and Technologies, 2020.23:e00140. [91] Wu, T., X. J. Liu, Y. Liu, M. Cheng, Z. F. Liu, G. M. Zeng, B. B. Shao, Q. H. Liang, W. Zhang, Q. Y. He, W. Zhang, Application of QD-MOF composites for photocatalysis: energy production and environmental remediation. Coordination Chemistry Reviews, 2020.403:213097. [92] Wang, Q., Q. Y. Gao, A. M. Al-Enizi, A. Nafady, S. Q. Ma, Recent advances in MOF-based photocatalysis: environmental remediation under visible light. Inorganic Chemistry Frontiers, 2020.7:300-339. [93] Shen, L., R. Liang, M. Luo, F. Jing, L. Wu, Electronic effects of ligand substitution on metal-organic framework photocatalysts: the case study of UiO-66. Physical Chemistry Chemical Physics, 2015.17:117-121. [94] Subudhi, S., S. Mansingh, S. P. Tripathy, A. Mohanty, P. Mohapatra, D. Rath, K. Parida, The fabrication of Au/Pd plasmonic alloys on UiO-66-NH2: an efficient visible light-induced photocatalyst towards the Suzuki Miyaura coupling reaction under ambient conditions. Catalysis Science Technology, 2019.9:6585-6597. [95] Qian, L., Y. Hou, Z. Yu, M. Li, F. Li, L. Sun, W. Luo, G. Pan, Metal-induced Z-scheme CdS/Ag/g-C3N4 photocatalyst for enhanced hydrogen evolution under visible light: The synergy of MIP effect and electron mediator of Ag. Molecular Catalysis, 2018.458:43-51. [96] Parvari, R., F. Ghorbani-Shahna, A. Bahrami, S. Azizian, M. J. Assari, M. Farhadian, A novel core-shell structured α-Fe2O3/Cu/g-C3N4 nanocomposite for continuous photocatalytic removal of air ethylbenzene under visible light irradiation. Journal of Photochemistry and Photobiology A: Chemistry, 2020.399:112643. [97] Ye, W., J. Hu, X. Hu, W. Zhang, X. Ma, H. Wang, Rational construction of Z‐scheme CuInS2/Au/g‐C3N4 heterostructure: experimental results and theoretical calculation. ChemCatChem, 2019.11:6372-6383. [98] Liang, Q., S. Cui, C. Liu, S. Xu, C. Yao, Z. Li, Construction of CdS@UIO-66-NH2 core-shell nanorods for enhanced photocatalytic activity with excellent photostability. Journal of Colloid and Interface Science, 2018.524:379-387. [99] Li, Z., J. Lyu, M. Ge, Synthesis of magnetic Cu/CuFe2O4 nanocomposite as a highly efficient Fenton-like catalyst for methylene blue degradation. Journal of Materials Science, 2018.53:15081-15095. [100] Pishnamazi, M., S. Koushkbaghi, S. S. Hosseini, M. Darabi, A. Yousefi, M. Irani, Metal organic framework nanoparticles loaded- PVDF/chitosan nanofibrous ultrafiltration membranes for the removal of BSA protein and Cr(VI) ions. Journal of Molecular Liquids, 2020.317. [101] Gesesse, G. D., A. Gomis-Berenguer, M.-F. Barthe, C. O. Ania, On the analysis of diffuse reflectance measurements to estimate the optical properties of amorphous porous carbons and semiconductor/carbon catalysts. Journal of Photochemistry and Photobiology A: Chemistry, 2020.398. [102] Liu, B., W. Wang, J. Wang, Y. Zhang, K. Xu, F. Zhao, Preparation and catalytic activities of CuFe2O4 nanoparticles assembled with graphene oxide for RDX thermal decomposition. Journal of Nanoparticle Research, 2019.21. [103] Kazemi, N., M. Mahdavi Shahri, Magnetically Separable and Reusable CuFe2O4 Spinel Nanocatalyst for the O-Arylation of Phenol with Aryl Halide Under Ligand-Free Condition. Journal of Inorganic and Organometallic Polymers and Materials, 2017.27:1264-1273. [104] Yue, Y.-N., Z.-L. Wang, L.-R. Yang, Y.-J. Zhao, H. Wang, J.-X. Lu, L-cysteine-functionalized CuPt: A chiral electrode for the asymmetric electroreduction of aromatic ketones. Electrochimica Acta, 2021.375. [105] Jürgensen, A., H. Raschke, N. Esser, R. Hergenröder, An in situ XPS study of L-cysteine co-adsorbed with water on polycrystalline copper and gold. Applied Surface Science, 2018.435:870-879. [106] Li, L., Q. Zhang, Y. Ding, X. Cai, S. Gu, Z. Cao, Application of l-cysteine capped core–shell CdTe/ZnS nanoparticles as a fluorescence probe for cephalexin. Analytical Methods, 2014.6:2715-2721. [107] Wei, S., C. Guo, L. Wang, J. Xu, H. Dong, Bacterial synthesis of PbS nanocrystallites in one-step with L-cysteine serving as both sulfur source and capping ligand. Scientific Reports, 2021.11:1216. [108] Han, Y., M. Liu, K. Li, Y. Zuo, Y. Wei, S. Xu, G. Zhang, C. Song, Z. Zhang, X. Guo, Facile synthesis of morphology and size-controlled zirconium metal–organic framework UiO-66: the role of hydrofluoric acid in crystallization. CrystEngComm, 2015.17:6434-6440. [109] Soomro, R. A., A. Nafady, Sirajuddin, N. Memon, T. H. Sherazi, N. H. Kalwar, L-cysteine protected copper nanoparticles as colorimetric sensor for mercuric ions. Talanta, 2014.130:415-422.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/81820	-
dc.description.abstract	固態介質Z-scheme 光觸媒是由三種元素包括兩個半導體和介質所組成。它比起傳統性type II異質結光觸媒擁有較高的氧化還原能力，且此機制可以抑制電子-電洞對的重組並吸收大量可見光。這些介質Z-scheme的潛力性質可與有機汙染物做氧化還原反應並光降解汙染物。然而，介質Z-scheme的問題出在於合成相對於傳統型type II較為複雜。大部分的光觸媒論文較少討論Z-scheme光觸媒合成之理論。此篇論文會詳細討論介質的合成方法及完整的Z-scheme合成過程。合成過程、化學鍵結(合成方案)及Z-scheme設計過程會被概述總結並且介質Z-scheme CuFe2O4/Cu/UiO66-NH2的設計被視為一個詳細設計概念的範例以證明自行總結的合成理論。其中此論文中合成理論的合成過程及合成方案會被運用以成功建構三層結構CuFe2O4/Cu/UiO66-NH2。為了瞭解配方對於光觸媒性質的影響，還原劑、分子間連結劑及UiO66-NH2的前驅物被調整不同比率以合成此光觸媒。並且，Rh6G染料與設計的光觸媒進行逐滴測試已證明光觸媒性質。最後，利用合成理論所得出的特定合成過程成功合成出新型設計的介質Z-scheme光觸媒。利用光觸媒逐滴測試最終得出調整三種試劑的配方中配方#2及#6成功顯現光觸媒活性。	zh_TW
dc.description.provenance	Made available in DSpace on 2022-11-25T03:04:21Z (GMT). No. of bitstreams: 1 U0001-2907202116254300.pdf: 4610657 bytes, checksum: b1382660ad5b2f362bf57aed976354d0 (MD5) Previous issue date: 2021	en
dc.description.tableofcontents	"ACKNOWLEDGEMENT ii ABSTRACT iii 摘要 iv Content v List of Figures viii List of Tables x Chapter 1 Introduction 1 Chapter 2 Literature review 3 2.1 Basic concept of photocatalyst 3 2.2 Brief introduction of heterojunction photocatalyst 5 2.2.1 Types of traditional heterojunction photocatalyst 5 2.2.2 Mechanism of type II heterojunction photocatalyst 6 2.2.3 Enhanced Z-scheme heterojunction photocatalyst 7 2.3 Dye Organic pollutants photodegradation 9 2.4 Synthesis method of metallic mediator in mediator Z-scheme 14 2.4.1 Metallic mediator synthesis method - Ag, Au, Cu, Pt, and Pd 14 2.4.2 With Ag mediator 14 2.4.3 With Cu mediator 14 2.4.4 With Au mediator 16 2.4.5 With Pt or Pd mediators 16 2.5 Design Z-scheme heterojunction CuFe2O4/Cu/UiO66-NH2 photocatalyst and thorough synthesis process determination 18 2.5.1 Brief introduction of designing mediator Z-scheme photocatalyst 18 2.5.2 Determination of degraded pollutants and two semiconductors of mediator Z-scheme 19 2.5.3 Synthesis process (Process A, B, C, D) and synthesis protocol (Protocol 1, 2, 3, 4) of mediator Z-scheme 21 2.5.4 Synthesis arrangement of two semiconductors - semiconductor I (SCI) and semiconductor II (SCII) of mediator Z-scheme 24 2.5.5 Determination of thorough synthesis process and protocol to mediator Z-scheme 25 Chapter 3 Experimental 31 3.1 Chemical 31 3.2 Synthesis process of Z-scheme photocatalyst CuFe2O4/Cu/UiO66-NH2 32 3.2.1 Synthesis of pure UiO66-NH2 32 3.2.2 Synthesis of spherical SCI CuFe2O4 32 3.2.3 Synthesis of SCI/M CuFe2O4/Cu 32 3.2.4 Synthesis of Z-scheme SCI/M/SCII CuFe2O4/Cu/UiO66-NH2 33 3.3 Characterization of Z-scheme photocatalyst CuFe2O4/Cu/UiO66-NH2 35 3.3.1 Powder X-Ray diffraction (PXRD) 35 3.3.2 Fourier transmittance infrared spectroscopy (FTIR) 35 3.3.3 Scanning electron microscopy (SEM) 35 3.3.4 Energy-dispersive X-ray spectroscopy (EDX) 36 3.3.5 Transmittance electron microscopy (TEM) 36 3.3.6 X-ray Photoelectron spectroscopy (VBXPS) 36 3.3.7 Differential reflectance spectroscopy (DRS) 37 3.3.8 Visible spectrophotometer 37 3.4 Photocatalytic dropwise test 38 3.4.1 Photocatalytic reactor set up 38 3.4.2 Photocatalytic dropwise test of Rh6G 38 Chapter 4 Results Discussion 40 4.1 Optical property of UiO66-NH2 and CuFe2O4 and mechanism of CuFe2O4/Cu/UiO66-NH2 40 4.2 Characterization of #1 to #9 43 4.2.1 X-ray Diffraction Analysis. 44 4.2.2 Functional groups of product CFO/C/UIN and intermediates 47 4.2.3 Morphology analysis of CFO, CFO/C, CFO/C/UIN 50 4.3 Photocatalysis tests 55 4.3.1 Photocatalytic dropwise test 55 4.3.2 Discussion of composite stoichiometry synthesis with photocatalytic performance 58 Chapter 5 Conclusions 60 References 64 "
dc.language.iso	en
dc.subject	機制	zh_TW
dc.subject	合成	zh_TW
dc.subject	示範	zh_TW
dc.subject	異質結	zh_TW
dc.subject	光觸媒	zh_TW
dc.subject	synthesis	en
dc.subject	photocatalyst	en
dc.subject	heterojunction	en
dc.subject	demonstration	en
dc.subject	mechanism	en
dc.title	合成及設計新型Z-scheme異質結ferrite/UiO66-NH2光觸媒與固態電子介質用於水中染料光降解	zh_TW
dc.title	Synthesis and design of a novel Z-scheme heterojunction ferrite/UiO66-NH2 photocatalyst with a solid-state electron mediator for photodegradation of dye in water	en
dc.date.schoolyear	109-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	賴君義(Hsin-Tsai Liu),黃志彬(Chih-Yang Tseng),朱曉萍
dc.subject.keyword	光觸媒,異質結,示範,機制,合成,	zh_TW
dc.subject.keyword	photocatalyst,heterojunction,demonstration,mechanism,synthesis,	en
dc.relation.page	79
dc.identifier.doi	10.6342/NTU202101899
dc.rights.note	同意授權(全球公開)
dc.date.accepted	2021-08-04
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	化學工程學研究所	zh_TW
dc.date.embargo-lift	2024-08-02	-
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