1 INTRODUCTION 7
1.1 Properties 8
1.2 Materials 10
1.3 Synthesis 11
1.3.1 Solvothermal Method 12
1.3.2 Electrochemical Method 12
1.3.3 Microwave-Assisted Method 13
1.3.4 Solvothermal Method 13
1.3.5 Diffusion Method 14
1.3.6 Mechanochemical Method 14
1.3.7 Sonochemical Method 15
1.3.8 Room Temperature Method 15
1.4 Markets and applications 16
1.5 Industry developments 2021-2022 17
2 MARKETS FOR METAL-ORGANIC FRAMWEWORKS (MOF) 18
2.1 Coatings 18
2.1.1 Properties 18
2.1.2 Applications 18
2.2 Gas Separation and Storage 19
2.2.1 Properties 19
2.2.1.1 Carbon capture 19
2.2.2 Applications 19
2.3 Biomedicine 20
2.3.1 Drug delivery 21
2.3.2 Antibacterials 22
2.3.3 Biosensors and bioimaging 23
2.4 Sensors 23
2.4.1 Properties 23
2.4.2 Applications 24
2.5 Air and water filtration 25
2.5.1 Properties 25
2.5.2 Applications 26
2.6 Water harvesting 27
2.7 Batteries and supercapacitors 28
2.8 Heat exchangers 28
2.9 HVAC 29
3 GLOBAL MARKET REVENUES 2018-2032 30
4 MOF PATENTS 35
4.1 Global MOF patent applications 35
4.2 Patenting by sector 36
4.3 Patenting by regional authority 37
5 MOF PRODUCER PROFILES 38 (24 company profiles)
6 EX-PRODUCERS 57
7 DISTRIBUTORS 59
8 REFERENCES 61
Tables
Table 1. Summary of MOFs. 8
Table 2. Markets and applications of Metal-organic frameworks (MOFs). 16
Table 3. MOF industry developments 2021-2022 17
Table 4. Applications of MOFs in gas storage and separation. 20
Table 5. Biomedical applications of MOFs. 20
Table 6. MOF sensor applications. 24
Table 7. Global market revenues for MOFs, 2018-2032, Millions USD. 30
Table 8. Global market revenues for MOFs, 2018-2031, Millions USD, medium revenues estimate. 31
Table 9. Global market revenues for MOFs, 2018-2031, Millions USD, high revenues estimate. 33
Figures
Figure 1. Examples of typical metal−organic frameworks. 7
Figure 2. Schematic drawing of a metal–organic framework (MOF) structure. 9
Figure 3. Number of synthesized MOFs reported per year . 10
Figure 4. MOF synthesis methods. 11
Figure 5. MOF synthesis methods historically. 11
Figure 6. Solvothermal synthesis of MOFs. 12
Figure 7. Electrochemical Synthesis method. 13
Figure 8. Schematic of continuous flow microfluidic device for producing MOFs. 14
Figure 9. Mechanochemical synthesis of MOFs. 15
Figure 10. NuMat’s ION-X cylinders. 19
Figure 11. Antibacterial mechanisms of metal–organic frameworks. 23
Figure 12. Capture mechanism for MOFs toward air pollutants. 26
Figure 13. Schematic of a MOF-based device for water harvesting. 27
Figure 14. MOF-coated heat exchanger. 29
Figure 15. Global market revenues for MOFs, 2018-2031, Millions USD. 30
Figure 16. Global market revenues for MOFs, 2018-2031, Millions USD, medium revenues estimate. 32
Figure 17. Global market revenues for MOFs, 2018-2031, Millions USD, high revenues estimate. 34
Figure 18. Global MOF patent applications 2001-2022. 35
Figure 19. Patent applications by sector. 36
Figure 20. Patent applications by authority. 37
Figure 21. Mosaic Materials MOFs. 45
Figure 22. MOF-based cartridge (purple) added to an existing air conditioner. 54
Figure 23. Molecular sieving membrane. 55
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