Adsorption Sites and Binding Nature of CO2 in Prototypical Metal−Organic Frameworks: A Combined Neutron Diffraction and First-Principles Study
Citations Over TimeTop 10% of 2010 papers
Abstract
We report a detailed study of CO2 adsorption in two important metal−organic framework (MOF) compounds (Mg-MOF-74 and HKUST-1). In both MOFs, the open metal ions were identified as the primary binding sites through neutron diffraction measurements. The relatively strong metal−CO2 binding was attributed to an enhanced electrostatic interaction, and vibrational mode analysis shows that the adsorbed CO2 molecule is strongly attached through one of its oxygen atoms while the rest of the molecule is relatively free. This high orientational disorder is the reason for the large apparent O−C−O bond bending angle derived from diffraction measurements. Our calculations give only a small degree of bond bending, suggesting that the CO2 adsorption on the open metal site is still largely physisorption. Interestingly, the overall metal−CO2 binding strength is right in the range which can facilitate both adsorption (CO2 capture) and desorption (MOF regeneration) under typical flue gas conditions.
Related Papers
- → Ab Initio Investigation of Physisorption of Molecular Hydrogen on Planar and Curved Graphenes(2001)297 cited
- → Theoretical and practical discussion of measurement accuracy for physisorption with micro- and mesoporous materials(2013)62 cited
- → Electronic structure calculations of physisorption and chemisorption on oxide glass surfaces(2005)53 cited
- → Influence of activated carbon surface oxygen functionalities on SO2 physisorption – Simulation and experiment(2013)33 cited
- → High-resolution physisorption techniques for the characterization of adsorbents and catalysts(1991)2 cited