Highly porous and stable metal-organic frameworks: Structure design and sorption properties

Gas sorption isotherm measurements performed on the evacuated derivatives o f four porous metalorganic frameworks (MOF-n), Zn(BDC).(DMF)(H2O) (DMF = N, N'-dimethylformamide, BDC = 1,4-benzenedicarboxylate) (MOF-2), Zn-3(BDC)(3) . 6CH(3)OH (MOF-3), Zn-2(BTC)NO3.(C2H5OH)(5)H2O (BTC = 1,3,5-benzenetricarb oxylate) (MOF-4), and Zn4O(BDC)(3).(DMF)(8)C6H5Cl (MOF-5), reveal type I is otherms for n = 2, 3, and 5, which is evidence of microporous and accessibl e channels having high structural integrity and organization. Although gas sorption into MOF-4 was not observed, careful examination of its ethanol so rption isotherms at 22 and 32 degrees C point to the presence of coordinati vely unsaturated zinc centers within its pores, which upon ethanol sorption undergo coordination transitions from 3- to 4-, 4- to 5-, and 5- to B-coor dination. MOF-n materials were produced by building the extended analogues of molecular metal carboxylate clusters-a strategy that has allowed the rea lization of the most porous and thermally stable framework yet reported: th e evacuated form of MOF-5 is especially stable in air at 300 degrees C and has a free pore volume representing 55-60% of its crystal as determined by gas sorption and single-crystal diffraction studies.