Bioinspired Mechanical Materials—Development of High-Toughness Ceramics through Complexation of Calcium Phosphate and Organic Polymers

IF 2.7 Q1 MATERIALS SCIENCE, CERAMICS Ceramics-Switzerland Pub Date : 2023-10-30 DOI:10.3390/ceramics6040130
Tadashi Mizutani, Natsuki Okuda
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Abstract

Inspired by the process of bone formation in living organisms, many studies have been conducted to develop organic–inorganic composite materials by preparing calcium phosphate crystals within solutions or dispersions of polymers with appropriate functional groups. Bones are composite materials consisting of organic polymers (mainly type I collagen), carbonated apatite, and water, with volume fractions of 35–45%, 35–45%, and 15–25%, respectively. Carbonated apatite in bone contributes to rigidity, while organic polymers and water contribute to toughness. The inorganic crystal, carbonated apatite, is a plate-shaped crystal with dimensions of 50 nm × 25 nm × 1–4 nm, generating a significant organic–inorganic interface, due to its nanoscale size. This interface is believed to absorb externally applied forces to dissipate mechanical energy to thermal energy. Creating such nanometer-scale structures using top-down approaches is challenging, making bottom-up methods, such as the coprecipitation of polymer and inorganic crystals, more suitable. In this account, efforts to develop eco-friendly mechanical materials using biomass, such as cellulose and starch, based on the bottom-up approach to bone-like composites are described.
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仿生机械材料——磷酸钙与有机聚合物络合制备高韧性陶瓷
受生物体骨形成过程的启发,许多研究通过在具有适当官能团的聚合物溶液或分散体中制备磷酸钙晶体来开发有机-无机复合材料。骨骼是由有机聚合物(主要是I型胶原蛋白)、碳酸磷灰石和水组成的复合材料,体积分数分别为35-45%、35-45%和15-25%。骨骼中的碳酸盐磷灰石有助于骨骼的刚性,而有机聚合物和水有助于骨骼的韧性。无机晶体碳酸盐磷灰石是一种片状晶体,尺寸为50 nm × 25 nm × 1-4 nm,由于其纳米级的尺寸,产生了重要的有机-无机界面。这个界面被认为吸收外部施加的力,将机械能转化为热能。使用自上而下的方法创建这种纳米级结构具有挑战性,因此自下而上的方法(如聚合物和无机晶体的共沉淀)更合适。在本报告中,描述了基于自下而上的类骨复合材料方法,利用生物质(如纤维素和淀粉)开发环保机械材料的努力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.00
自引率
7.10%
发文量
66
审稿时长
10 weeks
期刊最新文献
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