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JOURNAL ARTICLE

Functionalized MOFs for Enhanced CO2 Capture

Antonio TorrisiRobert G. BellCaroline Mellot‐Draznieks

Year: 2010 Journal:   Crystal Growth & Design Vol: 10 (7)Pages: 2839-2841   Publisher: American Chemical Society
DOI: 10.1021/cg100646e
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Abstract

Based on computational studies, we propose new metal−organic framework materials, in which the bridging ligands have been functionalized by different substituents, with the aim of improving the CO2 adsorption capacity of the material. The materials are based on the large-pore form of MIL-53(Al3+), with the following functional groups: OH-, COOH-, NH2-, and CH3-. For each form, adsorption heats and isotherms were simulated using the Grand Canonical Monte Carlo method which were found to be consistent with DFT calculations. The study illustrates the enormous impact of the functional groups in enhancing CO2 capture in the pressure range 0.01−0.5 bar and at room temperature. It also provides important insights into the structural factors which play a key role in the CO2 adsorption process in the functionalized MOFs. We propose the material (OH)2-MIL-53(Al3+) as an optimal candidate for improved CO2 capture at low pressures.

Keywords:
Adsorption Metal-organic framework Bridging (networking) Density functional theory Bar (unit) Chemistry Monte Carlo method Materials science Computational chemistry Thermodynamics Physical chemistry Computer science Physics Mathematics

Metrics

281
Cited By
12.07
FWCI (Field Weighted Citation Impact)
17
Refs
0.99
Citation Normalized Percentile
Is in top 1%
Is in top 10%

Citation History

Topics

Metal-Organic Frameworks: Synthesis and Applications
Physical Sciences →  Chemistry →  Inorganic Chemistry
Carbon Dioxide Capture Technologies
Physical Sciences →  Engineering →  Mechanical Engineering
Carbon dioxide utilization in catalysis
Physical Sciences →  Chemical Engineering →  Process Chemistry and Technology

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