Alkenyl/Thiol‐Derived Metal–Organic Frameworks (MOFs) by Means of Postsynthetic Modification for Effective Mercury Adsorption

Liu, Tao; Che, Jinxin; Hu, Yongzhou; Dong, Xiaowu; Liu, Xinyuan; Che, Chi‐Ming

doi:10.1002/chem.201403382

Cited by 100 publications

(37 citation statements)

References 78 publications

(15 reference statements)

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“…Obviously, the appearance of the silver signal at binding energies of 368.2 eV and 374.2 eV corresponding to the peaks of Ag 3d 5/2 and Ag 3d 3/2 , respectively, suggests that silver(I) has been loaded in the sample [29]. [19][20][21][22]. MOFs containing chelation ligands, such as 2,2'-bipyridine, can also afford metal ions, whereas the main issue however is the limitation of the choice of appropriate ligands [23][24][25][26].…”

Section: Characterization Of Mofsmentioning

confidence: 97%

“…It is postulated that if specific metal ions can be incorporated into the framework successfully, the adsorption performance for iodide will be enhanced greatly. Up to now, metal ions have been encapsulated into MOFs using various chelating methods, for example, postsynthetic method (PSM) [19][20][21][22] or in situ synthesis [23][24][25][26]. However, these methods reported may face the obstacles of relatively complex process or limitation of choice of appropriate ligands.…”

Section: Page 3 Of 23mentioning

confidence: 98%

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Enhanced removal of iodide from water induced by a metal-incorporated porous metal–organic framework

Zhao

Han

et al. 2015

Applied Surface Science

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Section: Characterization Of Mofsmentioning

confidence: 97%

Section: Page 3 Of 23mentioning

confidence: 98%

Enhanced removal of iodide from water induced by a metal-incorporated porous metal–organic framework

Zhao

Han

et al. 2015

Applied Surface Science

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“…19 Others have shown that post-synthetic modification allows thiol groups to be added to a pre-made MOF: in the case of MIL-101(Cr) this allowed formation of an Hg 2+ adsorbent. 20 In this paper we explore the possibility of producing a thiol-modified MIL-53, and use, for the first time, sulfur K-edge XANES spectroscopy to prove successful incorporation of a thiolated ligand into a MOF. To our knowledge the only previous attempt to add thiol groups to MIL-53 used post-synthetic reaction of amino-modified MIL-53 with mercaptoacetic acid.…”

Section: Introductionmentioning

confidence: 99%

Iodine sequestration by thiol-modified MIL-53(Al)

et al. 2016

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A thiol-modified version of the porous metal organic framework MIL-53 is synthesised in a single step using the functionalised ligand precursor 2,5-dithiol-1,4-benzenedicarboxylic acid and aluminium as the framework metal. Careful washing is needed to remove unreacted and dimerised linker from the material after synthesis, but once performed profile fitting of powder Xray diffraction shows that thiol-modified MIL-53(Al) presents a closed, narrow-pore, structure with unit cell volume ~1103 Å 3 (space group C2/c). The presence of intact thiol groups is confirmed using sulfur K-edge XANES spectroscopy and IR spectroscopy, while nitrogen BET surface area analysis and krypton and xenon adsorption isotherms reveal the porosity of the material. The thiol-modified solid is capable of iodine adsorption from the vapour phase and from solution and 2 an equilibrium uptake of ~325 mg per g is reached, which is higher than other reported modified forms of MIL-53. Infrared spectroscopy shows the disappearance of the S-H stretch after iodine adsorption, while sulfur K-edge XANES shows a complex spectrum, consistent with the formation of sulfenyl iodide but also oxidation of some sulfur to disulfide having occurred. We therefore propose that formation of covalent S-I bonds allows the sequestration of iodine by the porous solid, but that a proportion of the thiol groups are also in close enough proximity for the formation of disulfide links.

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“…[23] Most of these thrilling properties of MOFs,which are related to their porous character and rich host-guest chemistry, [24] can be tuned by an appropriate functionalization of the channels.T aking advantage of the methods provided by coordination chemistry,a na ccurate design effort [25] should thus lead to water-stable [26,27] MOFs for use as "mercury receptors". [28][29][30][31][32][33] Nature has evolved mechanisms to effectively distinguish one metal from another.H ow metal ions move to and from their target destinations in the active site of ametalloenzyme, or as structural components of other biomolecules such as nucleic acids,e fficiently contributes to the regulation of biological processes.A ni nteresting example within this context is the mercury reductase (MR), [34] ar edox enzyme that catalyzes the reduction of highly toxic Hg 2+ into more benign Hg 0 .T he active center of this enzyme represents as ource of inspiration for coordination chemists working in the area of mercury detoxification, and efforts trying to mimic it have been pursued. [34] MOFs could thus also find application as vessels encapsulating biological systems.…”

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confidence: 99%

Selective and Efficient Removal of Mercury from Aqueous Media with the Highly Flexible Arms of a BioMOF

et al. 2016

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A robust and water-stable metal-organic framework (MOF), featuring hexagonal channels decorated with methionine residues (1), selectively captures toxic species such as CH3 Hg(+) and Hg(2+) from water. 1 exhibits the largest Hg(2+) uptake capacity ever reported for a MOF, decreasing the [Hg(2+) ] and [CH3 Hg(+) ] concentrations in potable water from highly hazardous 10 ppm to the much safer values of 6 and 27 ppb, respectively. Just like with biological systems, the high-performance metal capture also involves a molecular recognition process. Both CH3 Hg(+) and Hg(2+) are efficiently immobilized by specific conformations adopted by the flexible thioether "claws" decorating the pores of 1. This leads to very stable structural conformations reminiscent of those responsible for the biological activity of the enzyme mercury reductase (MR).

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Alkenyl/Thiol‐Derived Metal–Organic Frameworks (MOFs) by Means of Postsynthetic Modification for Effective Mercury Adsorption

Cited by 100 publications

References 78 publications

Enhanced removal of iodide from water induced by a metal-incorporated porous metal–organic framework

Enhanced removal of iodide from water induced by a metal-incorporated porous metal–organic framework

Iodine sequestration by thiol-modified MIL-53(Al)

Selective and Efficient Removal of Mercury from Aqueous Media with the Highly Flexible Arms of a BioMOF

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