Texas A&M University / stable MOFs / stable MOF / Chemistry Research Center / stable N-based MOFs / N-based MOFs stable / /
IndustryTerm
isophthalate groups / thermal and chemical stability / high chemical similarity / energy barrier / 1D zinc-adenine chains / metal ion / chemical stabilities / exposed metal sites / transition metal ion / chemical and thermal stability / then metal / metal centers / metal-ligand interactions / metal-ligand bond / infinite chain / highvalence metal ions / metal ions / higher chemical stability / ligand-metal exchange constants / oil spill cleanup / porous coordination networks / high-valence metal ions / gas sorption isotherms / high chemical stability / metal-ion metathesis / metal / chemical reactions / high gas-uptake capacity / less labile metal-ligand bonds / metal exchange / gas sorption / metal-containing clusters / research / gas adsorption / increased chemical stability / pendant hydrophobic groups / gas storage / acidic aqueous solutions / ligand field stabilization energy / d10 transition metal / chemical stability / structure solution / less labile metal / amorphous products / acetonitrile solution / softer metal ions / labile metal / ligand-metal bonds / metal sites / chemicals / high-valence metal containing / /
Organization
U.S. Department of Energy / office of Science / Department of Chemistry / American Chemical Society / vol. / USA Department of Materials Science and Engineering / Chemistry Research Center / Texas A&M University / office of Basic Energy Sciences / /
Person
Hong-Cai Zhou / Y. S. Chua / V / V. Bon / V / Mathieu Bosch / Ion Metathesis / Y. Liu / V / Crystal Growth / /