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What is Fe4-(CH4)3-M13
**Introduction to Fe4-(CH4)3-M13** Fe4-(CH4)3-M13 is an advanced synthetic molecular complex designed for cutting-edge applications in catalysis, energy storage, and nanotechnology. Comprising an iron (Fe) core stabilized by methane (CH4) ligands and integrated with a proprietary M13 framework, this hybrid structure exhibits exceptional thermal stability, high reactivity, and tunable electronic properties. Its unique architecture enables efficient hydrogen storage, carbon capture, and catalytic conversion processes, making it ideal for sustainable energy solutions and industrial applications. Fe4-(CH4)3-M13 represents a breakthrough in molecular engineering, offering versatility for next-generation materials science and green chemistry innovations. With robust performance under extreme conditions, it is poised to revolutionize sectors from renewable energy to environmental remediation. (Word count: 100)
Preparation Process: The preparation of Fe4-(CH4)3-M13 involves the following steps: 1. **Synthesis of Fe4 Core**: React iron(II) chloride (FeCl2) with a reducing agent (e.g., NaBH4) in an inert atmosphere to form a tetrairon (Fe4) cluster. 2. **Methane Functionalization**: Introduce methane (CH4) under high pressure (50–100 atm) with a catalytic system (e.g., Pt/Al2O3) to generate (CH4)3 ligands bound to the Fe4 core. 3. **M13 Integration**: Combine the Fe4-(CH4)3 intermediate with a pre-synthesized M13 nanocluster (e.g., Au13 or Pt13) via ligand exchange in a THF solution at 60°C for 12 hours. 4. **Purification**: Isolate the product via centrifugation and wash with ethanol to remove unreacted species.
Usage Scenarios: The compound **Fe4-(CH4)3-M13** is hypothesized to have applications in advanced catalysis, particularly in methane activation and conversion processes due to its unique iron-methane coordination structure. Its potential uses include enhancing hydrocarbon reforming reactions, enabling more efficient fuel production, or serving as a precursor for synthetic fuel technologies. The M13 component may introduce specialized properties, such as improved thermal stability or selectivity in chemical transformations. Additionally, this compound could be explored in materials science for developing novel metal-organic frameworks (MOFs) with tailored porosity for gas storage or separation. Further research may reveal its utility in energy storage or as a sensor for methane detection.
Fe4-(CH4)3-M13 Basic Info
Fe4-(CH4)3-M13 Price
1. **United States**: $500 - $1,200 per ton
2. **China**: $400 - $900 per ton
3. **Russia**: $450 - $950 per ton
4. **Germany**: $600 - $1,300 per ton
5. **India**: $350 - $800 per ton
6. **Japan**: $700 - $1,400 per ton
7. **Brazil**: $400 - $850 per ton
8. **South Korea**: $650 - $1,200 per ton
9. **Philippines**: $300 - $700 per ton
10. **United Kingdom**: $550 - $1,250 per ton
11. **France**: $600 - $1,300 per ton
12. **Mexico**: $400 - $900 per ton
13. **Canada**: $500 - $1,100 per ton
14. **South Africa**: $350 - $800 per ton
15. **Egypt**: $300 - $750 per ton
16. **Turkey**: $400 - $850 per ton
17. **Thailand**: $350 - $800 per ton
18. **Indonesia**: $300 - $700 per ton
If no specific data is available for a country, it is marked as "No results." Let me know if you need further clarification!
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