Atomic Heat Contributions for Carbon Dioxide Adsorption in IRMOF-1

Abstract: A grand canonical Monte Carlo simulation has been carried out to investigate CO2 adsorption in the isoreticular metal–organic framework-1 [IRMOF-1, Zn4O­(1,4-benzenedicarboxylate)3] in the temperature range 170–310 K. We report adsorption isotherms, total isosteric heats, and the separate heat contributions resulting from fluid–fluid (FF) and fluid–IRMOF-1 (FS) interactions. For the first time, the contributions to isosteric heat from individual pore types and atom types in IRMOF-1 have been explored. The FS h… Show more

“…Recently, Klomkliang et al. explored the individual contributions of the pore types and atoms to the isosteric heat of adsorption of CO 2 in IRMOF‐1 [22] . The heat contributions were found to be dependent on the temperature and adsorption site.…”

A Molecular Insight into the Dehydration of a Metal–Organic Framework and its Impact on the CO₂ Capture

“…Recently, Klomkliang et al. explored the individual contributions of the pore types and atoms to the isosteric heat of adsorption of CO 2 in IRMOF‐1 [22] . The heat contributions were found to be dependent on the temperature and adsorption site.…”

A Molecular Insight into the Dehydration of a Metal–Organic Framework and its Impact on the CO₂ Capture

Insights into the heat contributions and mechanism of CO2 adsorption on metal–organic framework MIL-100 (Cr, Fe): Experiments and molecular simulations

Solid–solid thermal synthesis of bimetallic Ni/Zn embedded in N-doped porous carbon for efficient adsorptive separation based on CO2 adsorption at low pressure