g-C₃N₄ 光催化劑之開發及其在水環境中有機污染物降解之應用

Ashkan Miri; Ashkan Miri

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102183

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	施養信	zh_TW
dc.contributor.advisor	Yang-hsin Shih	en
dc.contributor.author	Ashkan Miri	zh_TW
dc.contributor.author	Ashkan Miri	en
dc.date.accessioned	2026-03-31T16:07:41Z	-
dc.date.available	2026-04-01	-
dc.date.copyright	2026-03-31	-
dc.date.issued	2026	-
dc.date.submitted	2026-02-11	-
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REACTION KINETICS MECHANISMS AND CATALYSIS 136:1423-1435.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102183	-
dc.description.abstract	隨著抗生素、鹵代酚類及多種新興污染物於水體中的濃度不斷升高，開發具高效率、可持續性且可在可見光驅動下運作的無金屬光觸媒已成為迫切需求。其中，聚合型氮化碳（polymeric carbon nitride, g-C₃N₄, CN）因其低成本、環境友善及可調控之電子結構而備受關注；然而，CN之實際應用仍受限於載流子快速復合、可見光吸收不足及氧化還原能力有限等問題。本論文旨在透過原生摻雜策略與異質結構界面工程，調控CN之能帶結構與電荷傳輸行為，以突破其固有性能瓶頸並提升其對環境污染物之光催化降解效能。本研究的第一部分聚焦於建構 TiO₂/CN 異質接面、Cl-CN 複合材料以及 S-TiO₂/Cl-CN 雙摻雜光觸媒，用以降解磺胺類抗生素與鹵代苯酚等污染物。透過系統性的材料鑑定（X光繞射分析、傅立葉轉換紅外光譜、穿透式電子顯微鏡、X光光電子能譜、紫外－可見光分光光譜、光致發光光譜）、動力學模型及活性氧物種（reactive oxygen species, ROS）分析，本研究證明了界面電荷轉移模式，包含 type-II、Z-scheme 與電子循環機制，可顯著提升光催化效率。此外，本研究採用反應曲面法優化合成與反應條件，成功實現對磺胺甲噁唑、4-溴苯酚與四溴雙酚A之高效降解。本研究的第二部分提出一套完全無金屬之原生摻雜策略，分別於 CN 晶格中導入碳、氮與氧摻雜（CCN、NCN、OCN）。摻雜後材料之電子結構經由密度泛函理論的能帶結構、投影態密度及HOMO–LUMO 前線軌域分析得到全面揭示。研究顯示，碳摻雜（CCN）可促使前線軌域產生顯著空間分離並形成高度離域化之 LUMO，從而有效抑制載流子復合並提升電荷遷移能力。電化學分析（電化學阻抗譜、光電流、循環伏安）亦證實 CCN 具最低界面電荷傳輸電阻與最強之光響應。電子順磁共振實驗顯示不同摻雜樣品之 ROS 生成途徑迥異，且光催化效率主要取決於表面之電荷有效利用率，而非活性氧物種之絕對濃度。綜合本論文之研究成果可知，原生摻雜能有效調控碳氮化物之內部電子構造，賦予材料新的反應性，從而顯著提升其在純水及複雜水體中對難降解污染物之光催化降解效能。相關之機制解析與實驗－計算整合策略提供一套可延展至未來多類環境應用之無金屬光觸媒設計藍圖，對綠色環境修復技術之發展具有重要意義。	zh_TW
dc.description.abstract	The increasing presence of pharmaceuticals, halogenated phenols, and emerging contaminants in aquatic systems necessitates the development of efficient, sustainable, and metal-free photocatalysts capable of operating under visible light. Polymeric carbon nitride (g-C3N4), CN, is an attractive candidate due to its low cost, environmental compatibility, and tunable electronic structure; however, its practical performance is limited by rapid charge recombination, insufficient visible light harvesting, and limited redox potential. This dissertation investigates rational strategies to overcome these shortcomings by engineering indigenous dopants and heterostructure systems that modulate the band structure and charge-transfer properties of CN-based photocatalysts. The first part of this work addresses the construction of TiO2/CN heterojunctions, Cl-CN composites, S-TiO2/Cl-CN hybrid structures, and 3D/2D Cs2Ag0.95Na0.05BiBr6/CN heterostructure for the degradation of sulfonamide antibiotics and phenolic pollutants. Through systematic characterization (XRD, FT-IR, TEM, XPS, UV-Vis, PL), kinetic modeling, and reactive oxygen species analysis, we demonstrate that interfacial chain charge-transfer pathways, such as type-II, Z-scheme, electron-cycling, and S-scheme mechanisms, significantly enhance photocatalytic efficiency. Response Surface Methodology (RSM) was applied to optimize synthesis and reaction parameters, achieving high removal efficiencies for pollutants such as SMX. The second part introduces a metal-free, indigenous-doping strategy in which carbon, nitrogen, and oxygen dopants are intrinsically incorporated into the CN framework (CCN, NCN, and OCN). These dopants fundamentally change the electronic properties of CN, as confirmed by DFT band structures, partial density of states (PDOS), and HOMO-LUMO analyses. The CCN exhibits promising orbital separation, enhanced band dispersion, and a highly delocalized LUMO, resulting in suppressed electron-hole recombination and significantly improved charge mobility. Electrochemical studies (EIS, photocurrent, CV) further validate that CCN possesses the lowest charge-transfer resistance and strongest photo-response. EPR measurements reveal distinct reactive-oxygen-species pathways among the doped catalysts, showing that photocatalytic performance is not only supported by the magnitude of ROS formation but by efficient charge utilization at the catalyst surface. The system showed outstanding photocatalytic performance in actual water environment, indicating the superb ability of indigenous element doping strategy toward improving the efficiency of CN-based photocatalysts. This study indicated versatile abilities of the carbon nitride-based photocatalysts for organic pollutant degradation, especially in real wastewater matrices, by improving visible light-harvesting ability, electrochemical properties, orbital tuning, and novel approaches to the charge carrier transfer mechanisms through the photocatalyst systems.	en
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dc.description.tableofcontents	Acknowledgment II 摘要 IV Abstract VI Table of contents VIII List of Tables XVII List of Figures XIX Introduction 1 1.1 Background 1 1.2 Photocatalytic process: mechanisms and challenges 4 1.2.1 Single semiconductor 6 1.2.2 Heterojunction semiconductors 7 1.2.2.1 Type I heterojunction 7 1.2.2.2 Type II heterojunction 8 1.2.2.3 Type III heterojunction 9 1.2.2.4 Z-Scheme heterojunction 9 1.2.2.5 Step-scheme (S-scheme) heterojunction 11 1.3 Motivation and scope of the present thesis 13 1.4 The objectives and research strategies 14 1.5 Novelty and scientific contribution 15 1.5.1 TiO2/CN heterostructure and electron chain transfer 15 1.5.2 Non-metal doping effect on S-TiO2/Cl-CN system 16 1.5.3 3D/2D Cs2Ag0.95Na0.05BiBr6/CN heterostructure 16 1.5.4 Enriching intrinsic elements 17 1.6 Thesis structure 17 Chapter 2: Literature review 21 2.1 Introduction 21 2.2 Structure of CN 23 2.2.1 Geometric structure 23 2.2.2 Band structure 23 2.3 Preparation methods of CN-based materials 24 2.4 CN-based nanocomposites 26 2.4.1 CN/metal oxide 26 2.4.2 CN/oxy acids 27 2.4.3 CN/perovskite 27 2.5 Doping strategy 29 2.5.1 Non-metal doping 29 2.5.1.1 Halogen doping 30 2.5.1.2 Carbon doping 33 2.5.1.3 Oxygen doping 35 2.5.1.4 Nitrogen doping 36 2.5.1.5 Other non-metal doping 37 2.5.2 Metal doping 44 2.6 Summary and scientific gaps 48 Chapter 3: Experimental methods 52 3.1 Chemicals 52 3.2 Preparation of CN/TiO2 photocatalyst 53 3.2.1 Synthesis of CN 53 3.2.2 CN/TiO2 photocatalyst preparation 53 3.3 Preparation of S-TiO2/Cl-CN photocatalyst 55 3.3.1 Synthesis of the CN and Cl-CN 55 3.3.2 Synthesis of S-TiO2 and S-TiO2/Cl-CN photocatalyst 55 3.4 Preparation of 3D/2D perovskite/CN heterostructure 56 3.4.1 Synthesis of BA2CsAg0.95Na0.05BiBr7 56 3.4.2 Synthesis of BA2CsAg0.95Na0.05BiBr7/CN heterostructure 57 3.5 Preparation of an indigenous non-metal doped CN photocatalyst 58 3.5.1 Catalyst preparation 58 3.5.2 Catalyst preparation design 59 3.6 Characterization 62 3.6.1 Structural and Morphological Characterization 62 3.6.2 Optical and Electrochemical measurements 63 3.6.3 Radical and mechanism study 65 3.7 Response Surface Methodology application 66 3.8 Photocatalytic experiments 68 3.8.1 4-bromophenol photodegradation 68 3.8.2 Experimental design and model assessment of sulfamethoxazole photodegradation 70 3.8.3 Bisphenol A photodegradation 71 3.8.4 Photodegradation of 2,4-dichlorophenol and teterabromobisphenol A 72 3.8.5 Environmental Condition effects 72 3.9 Computational details 73 3.10 Summary and Outlook 73 Chapter 4: Charge carrier chain transfer mechanism through the CN/TiO2 photocatalyst 75 4.1 Introduction 75 4.1.1 Background and Rationale 75 4.1.2 Scope and Aim of this Chapter 76 4.1.3 Novelty and Scientific Contribution 77 4.2 Characterization analysis of TiO2/CN heterostructure 78 4.2.1 Structural analyses 78 4.2.2 Morphological analyses 81 4.3 Optical properties and Electrochemical analyses of TiO2/CN heterostructure 84 4.3.1 DRS spectra and bandgap assessment 84 4.3.2 PL spectra and charge separation efficiency of TiO2/CN composite 85 4.3.3 Electrochemical analysis and charge resistance measurements 86 4.4 Photocatalytic evaluation of 4-BP 87 4.4.1 Photocatalytic performance and degradation kinetics 88 4.4.2 The effect of different reaction conditions on 4-BP photodegradation 89 4.5 Environmental conditions and stability performance of TiO2/CN 92 4.6 4-BP degradation pathway analysis 94 4.7 TiO2/CN photocatalytic mechanism study 96 4.7.1 Scavenger test 96 4.7.2 Band structure and electron chain transfer mechanism 97 4.8 Summary 100 4.9 Limitations and Outlook 101 Chapter 5: Visible-Light Driven S-TiO2/Cl-CN Photocatalyst for Sulfamethoxazole Degradation: RSM Optimization Approach 102 5.1 Introduction 102 5.1.1 Background and Rationale 102 5.1.2 Scope and Aim of this Chapter 104 5.1.3 Novelty and Scientific Contribution 105 5.2 Characterization analyses of S-TiO2/Cl-CN heterostructure 107 5.2.1 Lattice characterization 107 5.2.2 FT-IR and Raman spectroscopy 108 5.2.3 XPS and oxidation state analysis 110 5.2.4 Morphological characterization 114 5.3 Optical properties analysis of S-TiO2/Cl-CN photocatalyst 117 5.4 Electrochemical properties analysis of S-TiO2/Cl-CN heterostructure 121 5.4.1 Electrochemical Impedance Resistance (EIS) 121 5.4.2 Transient Photocurrent Responses spectra of S-TiO2/Cl-CN 122 5.4.3 Cyclic Voltammetry (CV) analysis 123 5.5 Photocatalytic Performance and RSM optimization for SMX degradation 126 5.5.1 Photocatalytic degradation of SMX 126 5.5.2 RSM modeling and ANOVA analysis 127 5.5.3 Effect of the independent variables on SMX photodegradation 131 5.5.4 Optimization of SMX photodegradation 136 5.5.5 Effect of Various Water Matrices 138 5.6 Mechanistic Insights and Charge-Transfer Pathway 141 5.6.1 Reactive Oxygen Species (ROS) and Radical Pathway 142 5.6.2 EPR Confirmation of Radical Species 143 5.6.3 Band structure and VB-XPS analysis 146 5.6.4 Post-Reaction Recovery and Stability Experiments 151 5.6.5 Structural Stability Evaluated by XRD and FT-IR Analyses 153 5.7 SMX Degradation Pathway Analysis (LC-MS) 154 5.8 Toxicity Assessment of SMX Intermediates 156 5.9 Summary 159 5.10 Limitations and Outlook 160 Chapter 6: Visible-Light Photocatalytic Degradation of Bisphenol A, Using a 3D/2D Cs2Ag0.95Na0.05BiBr6/CN Heterostructure 163 6.1 Introduction 163 6.1.1 Background and Rationale 163 6.1.2 Scope and Aims 165 6.1.3 Novelty and Scientific Contribution 166 6.2 Characterization analyses of Cs2Ag0.95Na0.05BiBr6/CN heterostructure 167 6.2.1 XRD analysis 167 6.2.2 XPS analysis of Cs2Ag0.95Na0.05BiBr6/CN heterostructure 169 6.2.3 Morphological assessment of Cs2Ag0.95Na0.05BiBr6/CN heterostructure 172 6.2.4 Optical analysis of Cs2Ag0.95Na0.05BiBr6/CN heterostructure 176 6.2.5 Electrochemical Analysis of Cs2Ag0.95Na0.05BiBr6/CN 179 6.3 Photocatalytic degradation evaluation 181 6.3.1 Effect of Different Operational Conditions on BPA Degradation 182 6.4 Recovery and Reusability Experiments 186 6.5 Radical Mechanism Study 188 6.6 S-scheme Charge-Transfer Mechanism of Cs2Ag0.95Na0.05BiBr6/CN heterostructure 190 6.7 Degradation Pathway Analysis of BPA 195 6.8 Summary 198 6.9 Limitations and Outlook 199 Chapter 7: One stone, Three Birds! Indigenous Element Doping of Carbon Nitride for Structural, Electronic, and Photocatalytic Enhancement 201 7.1 Introduction 201 7.1.1 Background and Rationale 201 7.1.2 Scope and Aims of This Chapter 202 7.1.3 Novelty and Scientific Contribution 204 7.2 Model Assessment of the Catalyst Preparation 205 7.2.1 CCN Optimization 209 7.2.2 NCN optimization 212 7.2.3 OCN Optimization 215 7.3 Characterization of indigenous non-metal dope CN photocatalysts 218 7.3.1 X-ray Diffraction analysis 219 7.3.2 IR analyses of doped photocatalysts 220 7.3.3 XPS analysis of doped photocatalysts 225 7.3.4 Elemental Analysis of the Synthesized Photocatalysts 229 7.3.5 Morphological Analysis of Synthesized Catalysts 230 7.3.6 BET Surface Area and Porosity Analysis 233 7.4 Optical properties Analysis of Indigenous non-metal dope CN photocatalysts 234 7.5 Partial Density of States (PDOS) Analysis 238 7.6 Electrochemical Characterization 242 7.6.1 EIS spectra 242 7.6.2 Transient Photocurrent Response 243 7.6.3 Cyclic Voltammetry (CV) Under Dark and Illuminated Conditions 245 7.7 Photocatalytic degradation assessment 246 7.8 Photocatalytic mechanism of indigenous doped catalysts 252 7.8.1 DFT Orbital analysis 252 7.8.2 EPR and reactive oxygen species analyses 257 7.9 Summary 266 7.10 Limitations and Outlook 267 Chapter 8: Conclusion and Future Perspective 269 8.1 Conclusion 269 8.2 Future Outlook and Research Direction 273 Chapter 9: References 278 Appendix 302	-
dc.language.iso	en	-
dc.subject	石墨氮化碳	-
dc.subject	光催化劑	-
dc.subject	異質結構	-
dc.subject	非金屬摻雜	-
dc.subject	graphitic carbon nitride	-
dc.subject	photocatalysts	-
dc.subject	heterostructure	-
dc.subject	non-metal doping	-
dc.title	g-C₃N₄ 光催化劑之開發及其在水環境中有機污染物降解之應用	zh_TW
dc.title	Development of g-C3N4 photocatalysts to degrade some organic contaminants in the aquatic environment	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	博士	-
dc.contributor.oralexamcommittee	董瑞安;連興隆;陳佳吟;郭大孚	zh_TW
dc.contributor.oralexamcommittee	Ruey-an Doong;Hsing-Lung Lien;Chia-Ying Chen;Dave Ta Fu Kuo	en
dc.subject.keyword	石墨氮化碳,光催化劑異質結構非金屬摻雜	zh_TW
dc.subject.keyword	graphitic carbon nitride,photocatalystsheterostructurenon-metal doping	en
dc.relation.page	310	-
dc.identifier.doi	10.6342/NTU202600766	-
dc.rights.note	未授權	-
dc.date.accepted	2026-02-12	-
dc.contributor.author-college	生物資源暨農學院	-
dc.contributor.author-dept	農業化學系	-
dc.date.embargo-lift	N/A	-
顯示於系所單位：	農業化學系

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