A Permanent Mesoporous Organic Cage with an Exceptionally High Surface Area

Zhang, Gang; Presly, Oliver; White, Fraser; Oppel, Iris M.; Mastalerz, Michael

doi:10.1002/ange.201308924

Angewandte Chemie

2014

DOI: 10.1002/ange.201308924

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A Permanent Mesoporous Organic Cage with an Exceptionally High Surface Area

Gang Zhang

Oliver Presly

Fraser White

et al.

Abstract: Recently, porous organic cage crystals have become a real alternative to extended framework materials with high specific surface areas in the desolvated state. Although major progress in this area has been made, the resulting porous compounds are restricted to the microporous regime, owing to the relatively small molecular sizes of the cages, or the collapse of larger structures upon desolvation. Herein, we present the synthesis of a shape-persistent cage compound by the reversible formation of 24 boronic este… Show more

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Cited by 146 publications

(74 citation statements)

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“…3a,b,e). This is among the highest surface areas 6 reported for a porous molecular organic solid, 18,35,36 and significantly higher than any of our analogous tetrahedral imine cages. 19,21 Racemic co-crystals of tubular cages DFT dimer calculations were performed to establish whether chiral recognition between cages might induce heterochiral window-to-window packing and hence the formation of isostructural nanotubes (Supplementary Information, Section 4.2, Supplementary Table 7).…”

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confidence: 55%

“…3 POCs are rigid molecules with a permanent internal void that is accessible to guests via 'windows' in the cage. [17][18][19] Control of structure and function for POCs can be difficult, however, because slight changes in the molecular structure 19 or the crystallization solvent 20 can cause a profound change in the crystal packing. Chiral window-towindow interactions (Fig.…”

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confidence: 99%

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Reticular synthesis of porous molecular 1D nanotubes and 3D networks

et al. 2016

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Synthetic control over pore size and pore connectivity is the crowning achievement for porous metal-organic frameworks. The same level of control has not been achieved for molecular crystals, which are not defined by strong, directional intermolecular coordination bonds. Hence, molecular crystallization is inherently less controllable than framework crystallization, and there are fewer examples of 'reticular synthesis'-where multiple building blocks can be assembled according to a common assembly motif.Here, we apply a chiral recognition strategy to a new family of tubular covalent cages, to create both 1-D porous nanotubes and 3-D diamondoid pillared porous networks.The diamondoid networks are analogous to metal-organic frameworks prepared from tetrahedral metal nodes and linear, ditopic organic linkers. The crystal structures can be rationalized by computational lattice energy searches, which provide an in silico screening method to evaluate candidate molecular building blocks. These results are a blueprint for applying the 'node and strut' principles of reticular synthesis to molecular crystals.Despite many advances in supramolecular chemistry, it is still challenging to control molecular crystallization to create a specific, useful property. 1,2 This is important in the emerging area of porous molecular solids, 3 which have practical advantages such as solution processability. The crystal packing in porous molecular crystals defines the pore dimensions, which in turn define properties such as guest selectivity. 4,5 The same challenge-control over solid state structure-applies to all 2 functional molecular crystals because crystal packing defines physical properties such as electronic band gap and thermal or electrical conductivity.A central paradigm in crystal engineering is to synthesize building blocks, or 'tectons', with strong, directional interactions, such as hydrogen bonding 6 or metal-ligand binding, 7 which direct assembly into a targeted three-dimensional superstructure (Fig. 1). 1,2,8,9 For metal-organic frameworks (MOFs) and porous coordination polymers (PCPs), directional metal-ligand bonds are used to do this (Fig. 1a). [10][11][12][13][14] Likewise, hydrogen bonding can be used to create organic molecular crystals with defined network structures (Fig. 1b). 9,15,16 We have used chiral recognition to assemble porous organic cages 3 (POCs) into structures with 3-D pore channels (Fig. 1c). 3 POCs are rigid molecules with a permanent internal void that is accessible to guests via 'windows' in the cage. [17][18][19] Control of structure and function for POCs can be difficult, however, because slight changes in the molecular structure 19 or the crystallization solvent 20 can cause a profound change in the crystal packing. Chiral window-towindow interactions (Fig. 1e,f) can direct these POCs to assemble into 3-D pore networks in several cases, 19,21,22 but this is not ubiquitous. For example, some cages require specific solvents to template the window-to-window packing. 20 The chiral cage CC3-S (...

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confidence: 55%

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confidence: 99%

Reticular synthesis of porous molecular 1D nanotubes and 3D networks

et al. 2016

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“…Unfortunately, highly porous crystal structures of discrete molecules are rare and difficult to predict a priori 7 ; furthermore, even when a small molecule can be organized into a porous structure, such structures are typically fragile after solvent removal. Recent work by Chen 8,9 , Cooper 10-12 , Mastalerz [13][14][15][16][17][18][19] and others [20][21][22] , has resulted in molecular crystals characterized by high porosity. These noncovalently held structures can be intrinsically or extrinsically porous.…”

mentioning

confidence: 99%

“…Mastalerz et al have reported intrinsically porous molecular crystals with surface areas over 3,500 m 2 g À 1 (ref. 18), and extrinsically porous ones with surface areas 43,000 m 2 g À 1 (ref. 14).…”

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confidence: 99%

Thermally robust and porous noncovalent organic framework with high affinity for fluorocarbons and CFCs

et al. 2014

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“…Most of these polyhedra are highly symmetric and achiral202122232425, and chiral molecular polyhedra with lower symmetry have attracted more and more attention because they increase the complexity of motifs and may bring more sophisticated functions262728293031. Generally, the construction of chiral molecular polyhedra follows two strategies: to use predetermined 3D chiral building blocks as the edges3032, vertices3334 or faces3536 of polyhedra to transfer 3D chirality of the components to the 3D chirality of the chiral structures, or to use achiral components to generate chiral metal-organic polyhedra373839404142 during a self-assembly process.…”

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confidence: 99%

Assembled molecular face-rotating polyhedra to transfer chirality from two to three dimensions

Wang

Yang

et al. 2016

Nat Commun

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In nature, protein subunits on the capsids of many icosahedral viruses form rotational patterns, and mathematicians also incorporate asymmetric patterns into faces of polyhedra. Chemists have constructed molecular polyhedra with vacant or highly symmetric faces, but very little is known about constructing polyhedra with asymmetric faces. Here we report a strategy to embellish a C3h truxene unit with rotational patterns into the faces of an octahedron, forming chiral octahedra that exhibit the largest molar ellipticity ever reported, to the best of our knowledge. The directionalities of the facial rotations can be controlled by vertices to achieve identical rotational directionality on each face, resembling the homo-directionality of virus capsids. Investigations of the kinetics and mechanism reveal that non-covalent interaction among the faces is essential to the facial homo-directionality.

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A Permanent Mesoporous Organic Cage with an Exceptionally High Surface Area

Cited by 146 publications

References 54 publications

Reticular synthesis of porous molecular 1D nanotubes and 3D networks

Reticular synthesis of porous molecular 1D nanotubes and 3D networks

Thermally robust and porous noncovalent organic framework with high affinity for fluorocarbons and CFCs

Assembled molecular face-rotating polyhedra to transfer chirality from two to three dimensions

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