Broadly Hysteretic H2 Adsorption in the Microporous Metal−Organic Framework Co(1,4-benzenedipyrazolate)
Citations Over TimeTop 1% of 2008 papers
Abstract
Reaction of Co(CF3SO3)2 with the new molecule 1,4-benzenedi(4'-pyrazolyl) (H2BDP) in N,N'-diethylformamide (DEF) at 130 degrees C generates the metal-organic framework Co(BDP).2DEF.H2O (1). X-ray analysis reveals the structure of 1 to contain chains of tetrahedrally ligated Co2+ ions linked through BDP2- ligands to generate a three-dimensional framework with 10 x 10 A2 channels. Thermogravimetric data shows the framework to have a high thermal stability, and complete desolvation occurs upon heating at 170 degrees C under dynamic vacuum for two days to afford 1d. X-ray powder diffraction data indicates that 1d possesses a substantially different structure, but converts back to 1 upon exposure to DEF, consistent with the presence of a flexible framework. Nitrogen adsorption isotherms measured for 1d at 77 and 87 K reveal an unprecedented five-step adsorption process and a Langmuir surface area of 2670 m2/g. In addition, high-pressure H2 adsorption data reveal hysteretic uptake and release, with hysteresis loops of width 1.1, 3.8, 13, and 27 bar that shift to higher pressures as the temperature increases from 50 to 65, 77, and 87 K, respectively. The high H2 uptake capacity of 5.5 excess wt % at 50 K suggests that such materials could potentially find utility for hydrogen storage via a kinetic trapping mechanism. Variable-temperature kinetics measurements have also allowed the first study of H2 diffusion within a metal-organic framework, revealing an energy barrier of 0.62 kJ/mol for H2 diffusing within the pores.
Related Papers
- → Exceptional H2 Saturation Uptake in Microporous Metal−Organic Frameworks(2006)1,256 cited
- → Unusual microporous polycatenane-like metal–organic frameworks for the luminescent sensing of Ln3+ cations and rapid adsorption of iodine(2012)98 cited
- → Xe adsorption and separation properties of a series of microporous metal–organic frameworks (MOFs) with V-shaped linkers(2017)46 cited
- → High Volumetric Hydrogen Storage Capacity using Interpenetrated Metal–Organic Frameworks(2017)45 cited
- → Generation of Hierarchical Porosity in Metal–Organic Frameworks by the Modulation of Cation Valence(2019)15 cited