Covalent Organic Frameworks

Tahir Rasheed is a researcher at the Interdisciplinary Research Center for Advanced Materials, King Fahd University of Petroleum and Minerals, Saudi Arabia. His research interests focus on multiple disciplines including controllable synthesis, characterization and self-assembly of polymeric materials, polymer-based composites, nanomaterials and nanocomposites, and hybrid nanocomposites, with special emphasis on their potential applications in the field of sensing and biosensing, electrocatalysis, and the degradation and quantification of various emerging pollutants. Ibrahim Yahia Yaagoob is a post-doctoral fellow in the Chemistry Department, King Fahd University of Petroleum and Minerals, Saudi Arabia. His research aims to synthesise and develop new innovative materials, including bio-inspired materials, to mitigate organic micropollutants and toxic materials from industrial wastewater. Chandrabhan Verma, PhD, works at the Interdisciplinary Research Center for Advanced Materials, King Fahd University of Petroleum and Minerals, Dhahran, Saudi Arabia. He is a member of the American Chemical Society (ACS). His research interests mainly focus on the synthesis and design of environment-friendly corrosion inhibitors used for several industrial applications. Dr. Verma received his PhD degree from the Department of Chemistry at IIT?BHU, Varanasi, India and MSc degree in organic chemistry (Gold Medalist). Dr. Verma is the author of several research and review articles in peer-reviewed international journals. He has also received several national and international awards for his academic achievements.

PART 1: FUNDAMENTALS
1. Introduction to COFs
2. Structural design and construction of COFs and COF-based nanocomposites
3. Material and chemistry of COFs
4. Fabrication approaches for COFs and COFs-oriented materials
5. Strategies for COFs functionalization
6. Strategies to improve sensitivity and selectivity of COFs

PART 2: COVALENT ORGANIC FRAMEWORKS-BASED NANOCOMPOSITES
7. COF carbon-based nanocomposites
8. COF metal oxide-based nanocomposites
9. COF polymer-based composites
10. COF chalcogenide-based nanocomposites

PART 3: COVALENT ORGANIC FRAMEWORKS-BASED NANOCOMPOSITES FOR ENERGY STORAGE
11. COFs-based nanocomposites for supercapacitors and pseudocapacitors
12. COFs-based nanocomposites for lithium-ion batteries
13. COFs-based nanocomposites for sodium-ion batteries
14. COFs-based nanocomposites for potassium-ion batteries
15. COFs-based nanocomposites for magnesium-ion batteries
16. COFs-based nanocomposites for zinc batteries
17. COFs-based nanocomposites for lithium sulphur batteries

PART 4: COVALENT ORGANIC FRAMEWORKS-BASED NANOCOMPOSITES FOR ENERGY CONVERSION
18. COFs-based nanocomposites for photocatalysis
19. COFs-based nanocomposites for electrocatalysis
20. COFs-based nanocomposites for carbon dioxide reduction
21. COFs-based nanocomposites for organic transformations
22. COFs-based nanocomposites for ionic conduction/transportation
23. COFs-based nanocomposites for proton conduction/transportation

PART 5: COVALENT ORGANIC FRAMEWORKS FOR ENVIRONMENTAL REMEDIATION
24. COFs-based nanocomposites for degradation of dyes
25. COFs-based nanocomposites for removal of pharmaceutical and personal care products
26. COFs-based nanocomposites for removal of heavy metals, anions, and radionuclides
27. COFs-based nanocomposites for capture of toxic gases
28. COFs-based nanocomposites for elimination of phenolic and endocrine disrupting chemicals
29. COFs-based nanocomposites in wastewater treatment

PART 6: COVALENT ORGANIC FRAMEWORKS FOR SENSING
30. COFs-based nanocomposites for fluorescent sensing
31. COFs-based nanocomposites for colorimetric sensing
32. COFs-based nanocomposites for electrochemical sensing
33. COFs-based nanocomposites for other sensing applications

PART 7: CHALLENGES AND FUTURE
34. Challenges and future prospects of COFs for energy and environmental applications