Crystalline Inorganic Frameworks with 56-Ring, 64-Ring, and 72-Ring Channels

Lin, Hsin Yau; Chin, Chih Yuan; Huang, Hui; Huang, Wen; Sie, Ming Jhe; Huang, Li; Lee, Yuan Han; Lin, Chia Her; Lii, Kwang Hwa; Bu, Xianhui; Wang, Sue Lein

doi:10.1126/science.1232097

Cited by 159 publications

(99 citation statements)

References 32 publications

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“…Here we are particularly interested in the separation of organic anions. Among reported MOFs, there are comparatively few permanently porous MOFs with positive framework (P-MOFs) 6,36,37 , whose rarity is also mirrored in other types of porous materials, including zeolites [38][39][40][41][42][43][44][45] . In addition, known P-MOFs often have low stability or small pore size that only permits the exchange of small inorganic anions 7,10 .…”

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Selective anion exchange with nanogated isoreticular positive metal-organic frameworks

et al. 2013

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Crystalline porous materials, especially inorganic porous solids such as zeolites, usually have negative frameworks with extra-framework mobile cations and are widely used for cation exchange. It is highly desirable to develop new materials with positive frameworks for selective anion exchange and separation or storage and delivery. Recent advances in metalorganic framework synthesis have created new opportunities in this direction. Here we report the synthesis of a series of positive indium metal-organic frameworks and their utilization as a platform for the anion exchange-based separation process. This process is capable of size-or charge-selective ion-exchange of organic dyes and may form the basis for size-selective ion chromatography. Ion-exchange dynamics of a series of organic dyes and their selective encapsulation and release are also studied, highlighting the advantages of metal-organic framework compositions for designing host materials tailored for applications in anion separation and purification.

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Selective anion exchange with nanogated isoreticular positive metal-organic frameworks

et al. 2013

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“…Müller et al [14] and Khan [15] introduced linkages between isolated cluster compounds to create porosity, while FØrey [16,17] proposed the scale chemistry method and predicted that the larger the structure building unit (SBU), the larger the pores. Very recently, Wang and coworkers [9] demonstrated that the channels in the phosphate framework can be successfully expanded by using templates with longer carbon chains. Of these three strategies, the first two are very successful with cluster-based building units, such as the germanates.…”

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confidence: 98%

“…Compared to the metal-organic frameworks (MOFs), where the pore size can be expanded and designed in a more rational way through reticular chemistry [4,10] or modular chemistry, [11,12] the expansion of the pore size in the inorganic crystalline materials is much slower. Several strategies [9,13] have been proposed to circumvent this challenge. Müller et al [14] and Khan [15] introduced linkages between isolated cluster compounds to create porosity, while FØrey [16,17] proposed the scale chemistry method and predicted that the larger the structure building unit (SBU), the larger the pores.…”

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confidence: 99%

“…[1][2][3][4] Mesoporous crystalline materials with a channel size above 2 nm are of special interest as the enlargement of the pores can enhance the diffusion of large organic molecules into the pores when the materials are used as catalysts or supports. However, there are only a few inorganic examples reported with such mesopores, such as ITQ-43[5] (a 28-ring germanium silicate), SU-M, [6] JLG-12 [7] (a 30-ring germanate), ITQ-37 [8] (a 30-ring germanium silicate), and NTHU-13, [9] a series of gallium zincophosphites with ring sizes from 24-ring to 72-ring. Compared to the metal-organic frameworks (MOFs), where the pore size can be expanded and designed in a more rational way through reticular chemistry [4,10] or modular chemistry, [11,12] the expansion of the pore size in the inorganic crystalline materials is much slower.…”

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Construction of Mesoporous Frameworks with Vanadoborate Clusters

Chen

Bacsik

et al. 2014

Angewandte Chemie

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A new porous vanadoborate was synthesized by employing the scale chemistry theory with the vanadoborate cluster V 10 B 28 . The twofold interpenetrated lvt network was assembled with zinc-containing elliptical vanadoborate clusters and Zn polyhedra. The single lvt framework contains a three-dimensional 38 38 20 ring channel system with the pore size (24.7 12.7 ) reaching the mesoscale, thus indicating the possibility of constructing 3D ordered mesopores with vanadoborate clusters. The porosity of the SUT-7 structure was confirmed by CO 2 adsorption of the as-synthesized materials.Crystalline inorganic materials including micro-or/and mesopores are of great importance because of their diverse channel systems and wide applications in adsorption, catalysis, and separation. [1][2][3][4] Mesoporous crystalline materials with a channel size above 2 nm are of special interest as the enlargement of the pores can enhance the diffusion of large organic molecules into the pores when the materials are used as catalysts or supports. However, there are only a few inorganic examples reported with such mesopores, such as ITQ-43[5] (a 28-ring germanium silicate), SU-M, [6] JLG-12 [7] (a 30-ring germanate), ITQ-37 [8] (a 30-ring germanium silicate), and NTHU-13, [9] a series of gallium zincophosphites with ring sizes from 24-ring to 72-ring. Compared to the metal-organic frameworks (MOFs), where the pore size can be expanded and designed in a more rational way through reticular chemistry [4,10] or modular chemistry, [11,12] the expansion of the pore size in the inorganic crystalline materials is much slower. Several strategies [9,13] have been proposed to circumvent this challenge. Müller et al. [14] and Khan [15] introduced linkages between isolated cluster compounds to create porosity, while FØrey [16,17] proposed the scale chemistry method and predicted that the larger the structure building unit (SBU), the larger the pores. Very recently, Wang and coworkers [9] demonstrated that the channels in the phosphate framework can be successfully expanded by using templates with longer carbon chains. Of these three strategies, the first two are very successful with cluster-based building units, such as the germanates. [7,18] Vanadoborates are interesting compounds assembled from vanadoborate clusters. Four types of vanadoborate clusters and their derivatives with different connections of VO 5 and BO 3 /BO 4 polyhedra are mainly reported: V 6 B 20 , [19,20] V 10 B 28 , [21,22] V 12 B 18 , [23][24][25] and V 12 B 16 [23, 26, 27] ( Figure 1). Although these clusters were discovered decades ago, few 3D framework structures have been reported in which they were used as building units. [27,28] In our previous study, we succeeded in linking V 12 B 18 to form the 3D framework SUT-6.[29] The V 12 B 18 cluster in SUT-6 has D 3d point-group symmetry and prefers a six-coordinated net (hxg in SUT-6). This high coordination number of V 12 B 18 makes its surround-

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“…[1][2][3] Many approaches toward the design and synthesis of inorganic frameworks have been explored; however, compounds containing extra-large channels are still limited. [2, 4,[6][7][8] In comparison with metal-organic frameworks (MOFs), the inorganic building units comprising various geometric polyhedra, flexible coordination behaviors, and assorted connectivities make the synthesis of inorganic frameworks with large pore sizes and channels difficult. One of the synthesis methods to prepare materials with open framework structures is the template-directed synthesis based on the charge density matching of the organic ammonium ions and the inorganic frameworks.…”

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Organic–Inorganic Hybrid Zinc Phosphate with 28‐Ring Channels

Wang

Lee

Chang

et al. 2014

Chemistry A European J

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An organic-inorganic hybrid zinc phosphate with 28-ring channels was synthesized by use of an organic ligand instead of organic amine template under a hydro(solvo)thermal condition. This crystalline zinc phosphate contains large channels constructed from 28 zinc and phosphate tetrahedral units. The walls of the channels consist of two types of zincophosphate chains, in which the Zn atoms are coordinated by 2,4,5-tri(4-pyridyl)-imidazole ligands as pendent groups. This compound exhibits yellow emission and interesting properties of removing cobalt, cadmium, and mercury cations from aqueous solution. A new two-dimensional organic-inorganic hybrid zincophosphate was also obtained by changing the solvent mixture ratios in the synthesis.

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Crystalline Inorganic Frameworks with 56-Ring, 64-Ring, and 72-Ring Channels

Cited by 159 publications

References 32 publications

Selective anion exchange with nanogated isoreticular positive metal-organic frameworks

Selective anion exchange with nanogated isoreticular positive metal-organic frameworks

Construction of Mesoporous Frameworks with Vanadoborate Clusters

Organic–Inorganic Hybrid Zinc Phosphate with 28‐Ring Channels

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