Abstract
During nuclear waste disposal process, radioactive iodine as a fission product can be released. The widespread implementation of sustainable nuclear energy thus requires the development of efficient iodine stores that have simultaneously high capacity, stability and more importantly, storage density (and hence minimized system volume). Here, we report high I2 adsorption in a series of robust porous metal–organic materials, MFM-300(M) (M = Al, Sc, Fe, In). MFM-300(Sc) exhibits fully reversible I2 uptake of 1.54 g g–1, and its structure remains completely unperturbed upon inclusion/removal of I2. Direct observation and quantification of the adsorption, binding domains and dynamics of guest I2 molecules within these hosts have been achieved using XPS, TGA-MS, high resolution synchrotron X-ray diffraction, pair distribution function analysis, Raman, terahertz and neutron spectroscopy, coupled with density functional theory modeling. These complementary techniques reveal a comprehensive understanding of the host–I2 and I2–I2 binding interactions at a molecular level. The initial binding site of I2 in MFM-300(Sc), I2I, is located near the bridging hydroxyl group of the [ScO4(OH)2] moiety [I2I···H–O = 2.263(9) Å] with an occupancy of 0.268. I2II is located interstitially between two phenyl rings of neighboring ligand molecules [I2II···phenyl ring = 3.378(9) and 4.228(5) Å]. I2II is 4.565(2) Å from the hydroxyl group with an occupancy of 0.208. Significantly, at high I2 loading an unprecedented self-aggregation of I2 molecules into triple-helical chains within the confined nanovoids has been observed at crystallographic resolution, leading to a highly efficient packing of I2 molecules with an exceptional I2 storage density of 3.08 g cm–3 in MFM-300(Sc).
Highlights
Nuclear power supplied 11% of the electricity in the world in 2016.1 it has ultrahigh energy density (500 million times higher than gasoline by volume), the widespread implementation of nuclear power has significant social effects and can be disastrous if not strictly and effectively controlled
Porous metal−organic frameworks (MOFs) are emerging hybrid solid adsorbents for a wide variety of gases,4a organic vapors,4b water4c and dyes.4d Constructed from metal ions bridged by organic ligands, MOFs often exhibit high porosity and tunable pore structures with desirable surface binding sites
The encapsulation of noble gases and heavy metal ions has been achieved in SBMOF-25a and ZrDMBD,5b respectively, demonstrating the potential application of MOFs for the cleanup of nuclear wastes
Summary
Nuclear power supplied 11% of the electricity in the world in 2016.1 it has ultrahigh energy density (500 million times higher than gasoline by volume), the widespread implementation of nuclear power has significant social effects and can be disastrous if not strictly and effectively controlled. Iodine isotopes, if released as an airborne contaminant, can pose significant health risks to humans through the respiratory system via both beta and γ radiation.[2] Various capture systems, including zeolites,3a,b chalcogels,3c microporous polymers,3d,e porous aromatic frameworks,3f covalent3g or hydrogen-bonded3h organic frameworks have been tested for the removal of I2. These systems, generally adopt irregular pore distributions, random adsorption sites and lack structural order, precluding the visualization of host−guest or guest−guest interactions. Adsorption of I2 has been studied in a number of MOFs showing varying capacity, Received: August 16, 2017 Published: October 11, 2017
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