| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 1785763 | Current Applied Physics | 2015 | 5 Pages |
•At higher pressures more CO2 than NO was adsorbed by Cu-BTC.•At higher pressures NO showed a tendency to desorb.•At lower pressure, the adsorption capacity of NO in Cu-BTC was almost to the point of saturation.•For the different pressure and gaseous mixture, more CO2 than NO was always adsorbed.
Environmental problems due to the discharge of gases, including NO and CO2, in addition, diseases caused by improper concentration of NO and CO2 in vivo must be resolved. In this study, Grand canonical Monte Carlo (GCMC) simulations are combined with density functional theory (DFT) to calculate the adsorption of NO and CO2 from a dual-component mixture to the Cu-BTC metal organic framework. The results show that the adsorption isotherms for various molar ratios of the gaseous mixture followed a Langmuir distribution. At higher pressures more CO2 than NO was adsorbed by Cu-BTC, with NO showing a tendency to desorb. However, better results for adsorption of NO were observed at lower pressures. For the different pressure and molar ratios of the gaseous mixture examined, more CO2 than NO was always adsorbed. Compared with three-way catalysts, Cu-BTC offers benefits to adsorption of CO2 and NO from gaseous mixtures without increased durability problems.
