Inorganic ionic polymerization: A bioinspired strategy for material preparation

Jian Zhang, Weifeng Fang, Zhaoming Liu, Ruikang Tang
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引用次数: 1

Abstract

Bioinspired materials with excellent properties have attracted intense interests of scientists, and the methodology for rationally design of these materials is crucially important. This review briefly introduces our recent achievements on inorganic ionic polymerization for bioinspired material preparation. The inorganic ionic polymerization realized the assembly of inorganic ions in a way similar to the polymerization in polymer chemistry, overcoming the limitation by classical nucleation pathway. It enabled the moldable construction of inorganic minerals and even the reconstruction of enamel tissue, which commonly only achieved by biomineralization. In the presence of organic molecules, the inorganic ionic polymerization could participate in the organic polymerization, resulting in hybrids with molecular-scaled organic-inorganic homogeneity. And furthermore, under the regulation of bio-inspired molecules, the condensed state of the assembled inorganic ions could show unusual behaviors: such as adding the flexibility to commonly fractal inorganic minerals, and flowability to solid mineral particles. It enabled the production of flexible mineral materials as plastic substitute, and the extrusion forming of moldable minerals under room temperature. The inorganic ionic polymerization demonstrated a promising way to synthesize inorganics in a more rational way, which may shed light on more advanced bio-inspired and biomimetic material.

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无机离子聚合:一种生物启发的材料制备策略
具有优异性能的仿生材料引起了科学家的极大兴趣,合理设计这些材料的方法至关重要。本文简要介绍了近年来无机离子聚合制备仿生材料的研究进展。无机离子聚合以类似于聚合物化学中聚合的方式实现了无机离子的组装,克服了经典成核途径的限制。它能够塑造无机矿物,甚至重建牙釉质组织,而这通常只能通过生物矿化来实现。在有机分子存在的情况下,无机离子聚合可以参与有机聚合,产生具有分子尺度有机-无机均匀性的杂化物。此外,在仿生分子的调控下,组装的无机离子的凝聚态可能表现出不同寻常的行为:例如为常见的分形无机矿物增加了灵活性,为固体矿物颗粒增加了流动性。它能够生产作为塑料替代品的柔性矿物材料,并在室温下挤出成型可成型矿物。无机离子聚合为以更合理的方式合成无机物提供了一种很有前途的方法,这可能为更先进的仿生生物材料提供线索。
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