San‐Tai Wang scite author profile

The effective capture and storage of radioiodine are of worldwide interest for sustainable nuclear energy. However, the direct observation of ambiguous binding sites that accommodate iodine is extremely rare. We presented herein a crystallographic visualization of the binding of iodine within mesoporous cages assembled from aluminum molecular rings. These nanocages are formed through π−π interactions between adjacent aluminum molecular rings. Compared with the general nanotubes arrangement, the supramolecular nanocage isomer exhibits better iodine adsorption behavior. The robust molecular nanocages demonstrate a high iodine vapor saturation uptake capacity of 50.3 wt % at 80 °C. Furthermore, the resulting adsorbent can be recycled. Singlecrystal X-ray diffraction reveals binding sites of molecular I 2 within the pores of the phenyl-based linkers stabilized by the strong I•••π interactions. These compounds represent an excellent model to deduce the trapping mechanism of guest molecules interacting with the host. In addition, this work develops a promising cluster-based aluminum material as iodine adsorbents.

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Designable Aluminum Molecular Rings: Ring Expansion and Ligand Functionalization

Geng

Liu

Wang

et al. 2020

Angew Chem Int Ed

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Presented herein are the AlIII molecular ring architectures from 8‐ring to 16‐ring. Although there are numerous reported cyclic coordination compounds based on transition metals, gallium, or lanthanides, the Al versions are less developed due to the fast hydrolysis nature of Al3+ ion. With the assistant of monohydric alcohols, a series of atomic precisely Al molecular rings based on benzoates are synthesized. The ring expansion of these Al‐rings from 8‐ring to 16‐ring is related to the monohydric alcohol structure‐directing agents. Moreover, the organic ligands on the Al‐rings can be modified by using various benzoate derivatives, which lead to tunable surface properties of the Al‐rings from hydrophilicity to ultra‐hydrophobicity. Importantly, 4‐aminobenzoic acid bridged 16‐ring is soluble in organic solvents and exhibits high solution stability revealed by mass spectroscopy. Ligand substitution also can be performed between these Al‐rings, which reveal controllable ligand functionalization of these Al‐rings.

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Record Aluminum Molecular Rings for Optical Limiting and Nonlinear Optics

Zheng

Wang

et al. 2022

Angew Chem Int Ed

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Crystalline cluster materials, a class of functional motif aggregations, provide a great opportunity for tuning the properties stemming from the flexible and accurate variation of inorganic and organic compositions. In this study, we demonstrate the effects of functional ligand and ring size regulation on the structures and third‐order nonlinear optical (NLO) properties. Revealed by the single‐crystal X‐ray analysis results, aluminum molecular ring expansion is achieved by 2×9 and 3×6 strategies. In terms of the given organic shells, we further tuned the aluminum molecular ring sizes from 3.0 nm to 1.7 nm. The picosecond Z‐scan measurements results revealed that the third‐order NLO performances do not only depend on the general conjugate interactions but are also related to hydrogen bonding, polarizability, and ring sizes. The large nonlinear absorption coefficient and onset prove that the observed samples are promising candidates for the field of nonlinear optics.

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San‐Tai Wang

Mesoporous Assembly of Aluminum Molecular Rings for Iodine Capture

Designable Aluminum Molecular Rings: Ring Expansion and Ligand Functionalization

Record Aluminum Molecular Rings for Optical Limiting and Nonlinear Optics

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