A facile synthesis tool of nanoporous carbon for promising H2, CO2, and CH4 sorption capacity and selective gas separation

The commercialization of hydrogen as a clean source of energy is a vital requirement for overcoming the anticipated energy crisis. In addition, the capture of CO2 and commercialization of methane as an efficient and clean alternative to polluting gasoline are important goals. To this end, we have de...

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Published in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2018, Vol.6 (45), p.23087-23100
Main Authors: Park, Jaewoo, Jung, Minji, Jang, Haenam, Lee, Kiyoung, Attia, Nour F, Oh, Hyunchul
Format: Article
Language:English
Subjects:
Activated carbon
Activation
Adsorption
Binary mixtures
Carbon dioxide
Carbon sequestration
Clean energy
Commercialization
Gas separation
Gases
Gasoline
Hydrogen
Hydrogen storage
Isotherms
Liquefaction
Materials selection
Methane
Nanoparticles
Nitrogen
Organic chemistry
Oxygen
Porous materials
Renewable resources
Selectivity
Storage capacity
Surface area
Surface chemistry
Sustainable yield
Temperature
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Summary:The commercialization of hydrogen as a clean source of energy is a vital requirement for overcoming the anticipated energy crisis. In addition, the capture of CO2 and commercialization of methane as an efficient and clean alternative to polluting gasoline are important goals. To this end, we have developed a nanoporous activated carbon material prepared from renewable resources that has a high storage capacity for various gases. Sugar beet leaves were converted to graphite flakes and decorated with polymer nanoparticles, giving rise to a highly porous activated carbon through chemical activation. The developed porous carbon has a high surface area (2800 m2 g−1) and specific pore volume (1.86 cm3 g−1), as well as high nitrogen and oxygen contents. The combination of high surface area, pore volume, and nitrogen and oxygen contents provided superior storage capacity for various gases. The total hydrogen storage capacities at 20 bar were 5.9 and 0.15 wt% at 77 and 298 K, respectively. In addition, the physical upper limit of hydrogen storage capacity was also evaluated using Brunauer–Emmett–Teller isotherms at the liquefaction temperature of hydrogen (20 K). A value of 14.1 wt% was obtained, which is the highest reported value for a porous carbon. The CO2 capture and CH4 storage capacities at room temperature and 20 bar were 19.65 and 7.6 mmol g−1, respectively, which are also among the highest values reported for porous carbon materials. Furthermore, the separation selectivity for CO2/CH4 binary mixtures was evaluated based on the ideal adsorbed solution theory (IAST) model and found to be 4.6.
ISSN:2050-7488
2050-7496
DOI:10.1039/c8ta08603f