Two Zeolite‐Type Frameworks in One Metal–Organic Framework with Zn<sub>24</sub>@Zn<sub>104</sub> Cube‐in‐Sodalite Architecture

Bu, Fei; Lin, Qipu; Zhai, Quan‐Guo; Wang, Le; Wu, Tao; Zheng, Shou‐Tian; Bu, Xianhui; Feng, Pingyun

doi:10.1002/ange.201203425

Cited by 17 publications

(13 citation statements)

References 85 publications

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“…The seven MOF used in this study were previously synthesized in our laboratory (Yilmaz et al, ) at around 100 g for each following the techniques given in the literature. These MOF were the titaniumbutoxide‐terephthalate MOF (Ti‐MOF) synthesized following the method of Vlasova et al (); the gamma‐cyclodextrine‐potassium hydroxide MOF (γ‐CD‐MOF) synthesized according to Moussa et al (); the chrome nitrate‐terephthalate MOF (Cr‐MOF) synthesized by the method of Li et al (); the aluminum‐MOF (Al‐MOF) synthesized according to Ma et al () with some modifications; the zinc nitrate‐2,5‐furandicarboxylic acid‐MOF (Zn‐MOF) synthesized following the solvothermal reaction given in Bu et al (); the magnesium‐MOF (Mg‐MOF) synthesized by following the technique of Spanopoulos et al () with some modifications; and the zinc‐2‐methylimidazole zeolytic type MOF (ZIF‐8‐MOF) synthesized according to Park et al (). After synthesis, these MOF were placed into colored glasses and stored at ambient temperature during the study.…”

Section: Methodsmentioning

confidence: 99%

Regeneration of Used Frying Oils by Selected Metal–Organic Frameworks as Adsorbents

Yılmaz

Güner

2018

J Americ Oil Chem Soc

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The aim of this study was to utilize seven synthesized metal-organic frameworks (MOF) and three natural clays as adsorbents in regenerating used frying oil. First, surface and pore properties, and morphologies of the adsorbents were determined, and used frying oil was treated at 0.1% addition (w/w) level. Then, physicochemical properties, mineral, and fatty-acid compositions of oil were analyzed. Finally, a recycling study was performed over five cycles with three selected adsorbents. Although there were only small improvements in oil color values, oil turbidity was significantly reduced with the adsorbents. Free fatty acidity values were reduced by 50.6% and 42.2% with Ti-MOF and zeolitic-MOF (ZIF-8-MOF) adsorbent treatments. Likewise, peroxide value reductions ranged from 43.6% with the Ti-MOF to 18.1% with natural zeolite. Reductions in the total polar materials (TPM) were the highest (42.5%) with aluminum-MOF (Al-MOF) followed by the ZIF-8-MOF (40.4%). Contents of aluminum, zinc, phosphorous, chromium, magnesium, and potassium were measured in the control and adsorbent-treated oil samples, and it was found that there was no leakage of minerals from the MOF into the oil, but rather some reductions due to adsorption. Furthermore, recycling studies with Ti-MOF, Cr-MOF, and sepiolite showed that the MOF can be used up to five times with only small activity losses compared with sepiolite. Overall, this study demonstrated the great potential of the MOF as adsorbents for frying oil regeneration, and pointed out that more research needed to design and synthesize new MOF structures for applying in the edible oil industry.

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Section: Methodsmentioning

confidence: 99%

Regeneration of Used Frying Oils by Selected Metal–Organic Frameworks as Adsorbents

Yılmaz

Güner

2018

J Americ Oil Chem Soc

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“…The MOFs used in this study were selected based on their safety knowledge for food applications, and synthesized in our laboratory at grams level with the given methods in the literature. The titanium butoxide-terephthalate MOF (Ti-MOF) was synthesized following the method of Vlasova et al 4 ; gamma-cyclodextrine-potassium hydroxide MOF (γ-CD-MOF) was synthesized according to Moussa et al 11 ; chrome nitrate-terephthalate MOF (Cr-MOF) was synthesized by the method of Li et al 12 ; aluminum-MOF (Al-MOF) was synthesized according to Ma et al 8 with some modifications; zinc nitrate-2,5-furandicarboxylic acid-MOF (Zn-MOF) was synthesized following the solvothermal reaction given in Bu et al 13 ; magnesium-MOF (Mg-MOF) was synthesized by following technique of Spanopoulos et al 9 ; and zinc-2-methylimidazole zeolytic type MOF (ZIF-8-MOF) was synthesized according to Park et al 14 The details of the syntheses could be reached in the given literature and in Yilmaz et al 15 Throughout the texts, tables and figures, the abbreviated MOF names given in the above brackets will be used. After enough amounts of synthesis, the MOFs were placed into colored glasses and stored at ambient temperature during the study.…”

Section: Methodsmentioning

confidence: 99%

“…; aluminum‐MOF (Al‐MOF) was synthesized according to Ma et al . with some modifications; zinc nitrate‐2,5‐furandicarboxylic acid‐MOF (Zn‐MOF) was synthesized following the solvothermal reaction given in Bu et al …”

Section: Methodsmentioning

confidence: 99%

Off‐Odor Removal from Fish Oil by Adsorbent Treatment with Selected Metal‐Organic Frameworks

Güner

Yılmaz

Yüceer

2019

Flavour & Fragrance J

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The limiting factor for consumption of liquid fish oil is its fishy off‐odor. The objectives of this study were to remove the off‐odors from liquid fish oil by adsorbent treatment with selected metal‐organic frameworks (MOFs), compare their activity with some natural clays, and also observe other changes developed in the oil after the treatments. Seven synthesized MOFs and three natural clays were added at 0.5% (w/w) into fish oil and mixed for 1.5 h at room temperature prior to filtration. The collected oil samples were analyzed for physico‐chemical properties, fatty acid, mineral and volatiles compositions, and sensory descriptions. Results indicated that for all the adsorbents tested, oil physico‐chemical properties improved, while no remarkable change was observed in fatty acid and mineral composition. Volatile composition analysis revealed that 68.8%, 46.2% and 44.5% reductions over total volatile concentrations were achieved using γ‐CD‐MOF, sepiolite and Ti‐MOF adsorbents, respectively. The panel described the oil with fishy, algae‐iodine, green and rancid terms. Some significant decreases in the measured sensory attributes were observed after the adsorbent treatments. Overall, although some significant reductions in volatiles were achieved, some off‐odor characteristics still remained at perceivable level. Hence, further studies focusing on designing specific MOFs are suggested.

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“…Unlike single-wall molecular aggregates 18 – 21 , the intrinsic structural particularity of double-shell MOPs sets a higher requirement for building components, especially for organic ligands in that how to reinforce structural subdivision is a key factor to be considered in the process of self-assembly. Because of this, with the exception of a few sporadic reports on metal–organic frameworks (MOFs) containing double-shell subunits so far 22 – 26 , double-shell macromolecular cages are much more rarely observed in the literature, with Pd-involved self-assembly being the commonest. This series of sphere-in-sphere assemblies with a general formula of Pd 24 L 24 are pioneered by Fujita and colleagues by selecting a tethered ligand on purpose 27 , and are developed in the groups of Li 28 and Mukherjee 29 by precise mapping of ligand coordination sites.…”

Section: Introductionmentioning

confidence: 99%

Equi–size nesting of Platonic and Archimedean metal–organic polyhedra into a twin capsid

Gan

Qin

et al. 2020

Nat Commun

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Inspired by the structures of virus capsids, chemists have long pursued the synthesis of their artificial molecular counterparts through self-assembly. Building nanoscale hierarchical structures to simulate double-shell virus capsids is believed to be a daunting challenge in supramolecular chemistry. Here, we report a double-shell cage wherein two independent metal-organic polyhedra featuring Platonic and Archimedean solids are nested together. The inner (3.2 nm) and outer (3.3 nm) shells do not follow the traditional "small vs. large" pattern, but are basically of the same size. Furthermore, the assembly of the inner and outer shells is based on supramolecular recognition, a behavior analogous to the assembly principle found in double-shell viruses. These two unique nested characteristics provide a new model for Matryoshka-type assemblies. The inner cage can be isolated individually and proves to be a potential molecular receptor to selectively trap guest molecules.

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Two Zeolite‐Type Frameworks in One Metal–Organic Framework with Zn₂₄@Zn₁₀₄ Cube‐in‐Sodalite Architecture

Cited by 17 publications

References 85 publications

Regeneration of Used Frying Oils by Selected Metal–Organic Frameworks as Adsorbents

Regeneration of Used Frying Oils by Selected Metal–Organic Frameworks as Adsorbents

Off‐Odor Removal from Fish Oil by Adsorbent Treatment with Selected Metal‐Organic Frameworks

Equi–size nesting of Platonic and Archimedean metal–organic polyhedra into a twin capsid

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Two Zeolite‐Type Frameworks in One Metal–Organic Framework with Zn24@Zn104 Cube‐in‐Sodalite Architecture

Cited by 17 publications

References 85 publications

Regeneration of Used Frying Oils by Selected Metal–Organic Frameworks as Adsorbents

Regeneration of Used Frying Oils by Selected Metal–Organic Frameworks as Adsorbents

Off‐Odor Removal from Fish Oil by Adsorbent Treatment with Selected Metal‐Organic Frameworks

Equi–size nesting of Platonic and Archimedean metal–organic polyhedra into a twin capsid

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Product

Resources

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Two Zeolite‐Type Frameworks in One Metal–Organic Framework with Zn₂₄@Zn₁₀₄ Cube‐in‐Sodalite Architecture