Chemical engineering Doctoral dissertation: Synthesis of catalysts based on Pt/SBA-15 modified with Al and/or B and their applicability on n-heptane hydroisomerization, tetralin hydrogenation and paracetamol detection

Synthesis of Catalysts Based on Pt/SBA-15 Modified with Al and/or B and Their Applicability on N-heptane Hydroisomerization, Tetralin Hydrogenation and Paracetamol Detection

Tác giả: NGO THỊ THANH HIEN

Lĩnh vực: Chemical Engineering Doctoral Dissertation

Nội dung tài liệu:

Luận án này tập trung vào việc tổng hợp các chất xúc tác hiệu quả dựa trên vật liệu SBA-15 được biến đổi với các nguyên tố Al và/hoặc B. Các chất xúc tác này sau đó được đánh giá về khả năng ứng dụng trong ba lĩnh vực chính: phản ứng hydroisomer hóa n-heptan, phản ứng hydro hóa tetralin và phát hiện paracetamol. Nghiên cứu khám phá ảnh hưởng của bản chất nguyên tố lạ (heteroatom) lên tính chất axit của các chất nền M-SBA-15 đã biến đổi và các chất xúc tác lưỡng chức 0.5% Pt/M-SBA-15. Đồng thời, luận án cũng xem xét khả năng ứng dụng của các chất xúc tác 1% Pt/M-SBA-15 trong việc phát hiện paracetamol bằng phương pháp điện hóa sử dụng các điện cực biến đổi hóa học.

Mục lục chi tiết:

• STATUTORY DECLARATION
• ACKNOWLEDGEMENT
• CONTENTS
• LIST OF ABBREVIATIONS
• LIST OF FIGURES
• LIST OF TABLES
• INTRODUCTION
• THE NEW CONTRIBUTION OF THE DESSERTATION
• CHAPTER 1. LITERATURE REVIEW
• 1.1. Mesoporous material and ordered mesoporous silica SBA-15
• 1.2. The modified SBA-15 materials and applications
• 1.3. The hydroisomerization of n-alkane over bifunctional catalysts
• 1.3.1. Metal function of bifunctional catalysts
• 1.3.2. Acid function of bifunctional catalysts
• 1.4. Hydrogenation of polynuclear aromatic hydrocarbon (PAHs)
• 1.4.1. Hydrogenation of polynuclear aromatic hydrocarbon (PAHs)
• 1.4.2. Catalysts for PAHs hydrogenation
• 1.5. Overview of paracetamol detection.
• 1.5.1. Introduction of paracetamol
• 1.5.2. Electroanalytical methods based on using chemically modified electrodes (CMEs) for paracetamol detection.
• 1.5.3. Chemically modified electrodes (CMEs) for PA detection
• 1.6. Conclusions
• CHAPTER 2. EXPERIMENTAL
• 2.1. Preparation of catalysts
• 2.1.1. Direct synthesis procedure of M-SBA-15 (where M=Al and/or B)
• 2.1.2. Indirect synthesis of B/SBA-15
• 2.1.3. Synthesis of Pt/M-SBA-15 (where M=Al-, B- and Al-B-) catalysts
• 2.2. Electrochemical procedure
• 2.2.1. Preparation of Pt/M-SBA-15-GPE electrodes
• 2.2.2. Preparation of supporting electrolyte and standard solution of paracetamol
• 2.3. Catalyst characterization techniques
• 2.3.1. X-Ray Diffraction
• 2.3.2. Transmission electron microscopy (TEM)
• 2.3.3. Fourier Transformed Infrared Spectroscopy (FT-IR)
• 2.3.4. Temperature Programmed Desorption (NH3-TPD)
• 2.3.5. Nitrogen adsorption-desorption
• 2.3.6. Thermal analysis
• 2.3.7 Inductively coupled plasma optical emission spectrometry (ICP – OES)
• 2.3.8. Pyridine-FTIR
• 2.3.9. Energy Dispersive X-Ray Spectroscopy (EDS or EDX)
• 2.3.10. 11B MAS NMR spectroscopy
• 2.4. Hydroisomerization activity test
• 2.5. Hydrogenation activity test
• 2.6. Electrochemical measurements
• CHAPTER 3. RESULTS AND DISCUSSION
• 3.1. Effect of preparation methods of support.
• 3.2. Characterizations of modified SBA-15 supports
• 3.2.1. X-ray diffraction (XRD)
• 3.2.2. Nitrogen physisorption isotherms.
• 3.2.3. Transition electron microscopy (TEM)
• 3.2.4. Fourier-transform infrared spectroscopy (FTIR)
• 3.2.5. EDX analysis
• 3.2.6. 11B MAS-NMR spectroscopy
• 3.2.7. Ammonia Temperature- Programmed Desorption (NH3-TPD)
• 3.2.8. FTIR spectra of chemisorbed pyridine
• 3.3. Characterizations of Pt/modified SBA-15 catalysts
• 3.3.1. Nitrogen physisorption isotherms
• 3.3.2. X-ray diffraction (XRD)
• 3.3.3. Transition electron microscopy (TEM)
• 3.3.4. NH3-TPD profiles
• 3.4. Performance of platinum supported on modified SBA-15 catalysts for hydro-isomerization of n-heptane
• 3.4.1. Effect of the acidic supports on hydroisomerization activity of catalysts
• 3.4.2. Effect of temperature and reaction time in the hydroisomerization of n-heptane
• 3.4.3. Cracked product yield and coke formation
• 3.5. Performance of platinum supported on modified SBA-15 catalysts for hydrogenation of tetralin
• 3.5.1. The results of GC-MS analysis of hydrogenation of tetralin
• 3.5.2. Effect of reaction temperature and pressure on catalytic activity
• 3.5.3. Effect of the acidity of modified supports on catalytic activity.
• 3.5.4. Coke formation
• 3.6. The mesoporous catalysts of Pt loaded on modified SBA-15 material for the paracetamol detection
• 3.6.1. Characterization of 1%Pt/Al-SBA-15 catalyst
• 3.6.2. Electrochemical characterization of Pt/Al-SBA-15-GPE electrode material
• 3.6.3. Electrochemical impedance spectroscopy measurements at Pt/Al-SBA-15-GPE electrode
• 3.6.4. Analytical characterization of Pt/Al-SBA-15-GPE electrode material
• 3.6.5. Interference study
• 3.6.6. Real sample analysis
• CONCLUSIONS
• PUBLICATIONS OF THE DISSERTATION
• REFERENCES