One‐Pot Multiple Metal–Organic Framework Formation: Concomitant Generation of Structural Isomers or of Drastically Distinct Materials

Cheansirisomboon, Achareeya; Salinas‐Uber, Jorge; Massera, Chiara; Roubeau, Olivier; Youngme, Sujittra; Gámez, Patrick

doi:10.1002/ejic.201402475

Cited by 15 publications

(13 citation statements)

References 89 publications

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“…XXXX, XXX, XXX−XXX (DMF) 2 ] (the latter adopts the sra topology but has mistakenly reported as lvt). 3g, 18 Photophysical Studies. As seen in Figure 7, illumination with a laboratory UV lamp (ca.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Additionally, AEMOF-3 is the only example of alkaline earth metal ion−H 2 dhtp 2− MOF with a 2-D structure (all other examples display 3D frameworks). Finally, comparing the topological features of AEMOF-2−6 with those of known alkaline earth−H 2 dhtp 2− MOFs it was realized that AEMOFs-2,3 display network topologies not shown by other AEMOFs, whereas AEMOF-5 adopts the same topology with the compound [Mg 3 (H 2 dhtp) 3 (DMF) 6 ]·0.75H 2 O,18 and AEMOF-4,6 adopt the same topology with [Mg(H 2 dhtp)-…”

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confidence: 97%

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Alkaline Earth Metal Ion/Dihydroxy–Terephthalate MOFs: Structural Diversity and Unusual Luminescent Properties

et al. 2015

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Alkaline earth (group 2) metal ion organic frameworks (AEMOFs) represent an important subcategory of MOFs with interesting structures and physical properties. Five MOFs, namely, [Mg2(H2dhtp)2(μ-H2O)(NMP)4] (AEMOF-2), [Mg2(H2dhtp)1.5(DMAc)4]Cl·DMAc (AEMOF-3), [Ca(H2dhtp)(DMAc)2] (AEMOF-4), [Sr3(H2dhtp)3(DMAc)6]·H2O (AEMOF-5), and [Ba(H2dhtp)(DMAc)] (AEMOF-6) (H4dhtp = 2,5-dihydroxy-terepthalic acid; DMAc = N,N-dimethylacetamide; NMP = N-methylpyrrolidone), are presented herein. The reported MOFs display structural variety with diverse topologies and new structural features. Interestingly, AEMOF-6 is the first example of a Ba(2+)-H2dhtp(2-) MOF, and AEMOF-5 is only the second known Sr(2+)-H2dhtp(2-) MOF. Detailed photoluminescence studies revealed alkaline earth metal ion-dependent fluorescence properties of the materials, with the heavier alkaline earth metal ions exhibiting red-shifted emission with respect to the lighter ions at room temperature. A bathochromic shift of the emission was observed for the MOFs (mostly for AEMOF-3 and AEMOF-4) at 77 K as a result of excited state proton transfer (ESIPT), which involves an intramolecular proton transfer from a hydroxyl to an adjacent carboxylic group of the H2dhtp(2-) ligand. Remarkably, AEMOF-6 displays rare yellow fluorescence at room temperature, which is attractive for solid state lighting applications. To probe whether the alkaline earth metal ions are responsible for the unusual luminescence properties of the reported MOFs, the potential energy surfaces (PESs) of the ground, S0, and lowest energy excited singlet, S1, states of model complexes along the intramolecular proton transfer coordinate were calculated by DFT and TD-DFT methods.

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Section: ■ Introductionmentioning

confidence: 99%

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confidence: 97%

Alkaline Earth Metal Ion/Dihydroxy–Terephthalate MOFs: Structural Diversity and Unusual Luminescent Properties

et al. 2015

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“…A search of the Cambridge Crystallographic Data Centre reveals 5 different coordination polymers derived from magnesium and the di-anion of 2,5-dihydroxyterephthalate, in addition to the aforementioned CPO-26-Mg and CPO-27-Mg, all of which contain a three-dimensional coordination framework. One was prepared from DMF, [26] one from DMF in the presence of NEt 3 , [27] and one from aqueous DMA, [28] whilst the remaining two were prepared from DMA or aqueous N-methyl pyrrolidone. [29] This is the first example of a material prepared from a predominately aqueous solution.…”

Section: Crystallographymentioning

confidence: 99%

Synthesis and crystallographic characterisation of Mg(H 2 dhtp)(H 2 O) 5 ·H 2 O

Henkelis

McCormick

Cordes

et al. 2016

Inorganic Chemistry Communications

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“…It turns out that the topology observed for the Cd-MOF is heretofore unprecedented. The formation of two different types of MOFs with different compositions concomitantly in the same reaction vessel is a rare occurrence. − As mentioned earlier, the reaction of H 4 L with Zn(II) salt at 90 °C gives rise to two different forms, referred to as Zn-Lsqc and Zn-Ldia . Quite remarkably, temperature dependence of the formation of concomitant MOFs revealed that one observes the formation of Zn-Ldia exclusively at 110 °C, which suggests that the latter corresponds to the thermodynamic form of the two MOFs.…”

Section: Resultsmentioning

confidence: 99%

“…Metal–organic frameworks (MOFs) are exotic porous materials that permit diverse applications such as gas storage, molecular sieving, sensing, magnetism, catalysis, bioimaging, drug delivery, etc. − Synthesis of MOFs with predefined framework structures remains still a challenge, as the reactions to access them depend on a variety of parameters, which include metal–linker ratio, pH, solvent employed, temperature, coordination number and geometry of the metal ion, nature of the counterion used, additive, etc. − It is needless to say that the structural attributes of an organic linker play a crucial role in determining the structures as well as topologies of the derived frameworks due to variable coordination modes, conformational flexibility, and presence of different secondary functional groups. , The synthesis/crystallization process by which the MOFs are accessed is sensitive to different reaction parameters, and often results in the occurrence of unusual secondary building units (SBUs). , The latter in turn lead to formation of interesting and varied network structures. Consequently, formation of two or more different metal–organic frameworks from the same synthesis/crystallization pot with intriguing structure types is not rare, which indeed subverts the anticipated framework structures based on connectivity dispositions of the linker and coordination preferences of the metal ions. − In principle, one may access coordination polymers with the same framework chemical formula, but different structures or those that differ in terms of both chemical formula as well as structural attributes. The former have been popularly termed “supramolecular isomers”, ,− while those differing in chemical formulas have been termed “structural isomers”. , The literature reveals abundant examples of solvent-, template-, counterion-, additive-, and temperature-dependent formation of isomeric coordination polymers. ,− MOFs being materials whose structures and chemical functionalities can be tuned in a bottom-up approach through the linkers modifications, the structure–property relationships help in deciphering subtle factors that are important for their functional properties.…”

Section: Introductionmentioning

confidence: 99%

Metal-Mediated Self-Assembly of a Twisted Biphenyl-Tetraacid Linker with Semi-rigid Core and Peripheral Flexibility: Concomitant Formation of Compositionally Distinct MOFs

Seth

Savitha

Moorthy

2018

Crystal Growth & Design

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A semi-rigid organic linker, namely, 3,3′,5,5′-tetrakis(4-(α-carboxy)methoxyphenyl)-2,2′,6,6′-tetramethoxy-1,1′-biphenyl (H 4 L), was designed and synthesized to access metal–organic frameworks (MOFs). While the ortho-methoxy substituents in the biphenyl core of H 4 L were surmised to twist the aromatic planes and impart porosity to the resultant MOFs, the (α-carboxy)methoxyphenyl moieties at the periphery were envisaged to enable requisite flexibility for metal–ligand coordination polymerization. The reactions of H 4 L with Cd, Mn, and Zn salts indeed yielded MOFs, i.e., Cd-L, Mn-L, Zn-Lsqc, and Zn-Ldia, with interesting structural features and unusual inorganic SBUs. In particular, the reaction of H 4 L with ZnI2 in DMF at 90 °C over 2 days led to concomitant formation of a pair of compositionally distinct Zn-MOFs, i.e., Zn-Ldia and Zn-Lsqc, each of which could be accessed exclusively by controlling the reaction conditions. The diversity observed in the structures of MOFs formed with the linker H 4 L with a limited number of metal ions sufficiently emphasizes the importance of the attributes of the linker in the formation of 3D MOFs; the latter are desirable from the stability and exfoliation points of view when the MOFs are explored for applications such as gas storage, catalysis, etc. In corroboration of our previous results, it emerges that the flexibility that is built into the structure of the organic linker, both at the central core and at the periphery, leads to concomitant formation of compositionally distinct MOFs in addition to diverse SBUs and disparate framework topologies.

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One‐Pot Multiple Metal–Organic Framework Formation: Concomitant Generation of Structural Isomers or of Drastically Distinct Materials

Cited by 15 publications

References 89 publications

Alkaline Earth Metal Ion/Dihydroxy–Terephthalate MOFs: Structural Diversity and Unusual Luminescent Properties

Alkaline Earth Metal Ion/Dihydroxy–Terephthalate MOFs: Structural Diversity and Unusual Luminescent Properties

Synthesis and crystallographic characterisation of Mg(H 2 dhtp)(H 2 O) 5 ·H 2 O

Metal-Mediated Self-Assembly of a Twisted Biphenyl-Tetraacid Linker with Semi-rigid Core and Peripheral Flexibility: Concomitant Formation of Compositionally Distinct MOFs

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