珍珠层中纳米晶粒旋转与变形的原位观察。

In situ observation of nanograin rotation and deformation in nacre.

作者信息

Li Xiaodong, Xu Zhi-Hui, Wang Rizhi

机构信息

Department of Mechanical Engineering, University of South Carolina, 300 Main Street, Columbia, South Carolina 29208, USA.

出版信息

Nano Lett. 2006 Oct;6(10):2301-4. doi: 10.1021/nl061775u.

DOI:10.1021/nl061775u

PMID:17034101

Abstract

Nacre is a natural nanocomposite material with superior mechanical strength and toughness. What roles do the nanoscale structures play in the inelasticity and toughening of nacre? Can we learn from this to produce nacre-like nanocomposites? Here we report in situ dynamic atomic force microscope observations of nacre with aragonite nanograins (nanoparticles) of an average grain size of 32 nm, which show that nanograin rotation and deformation are the two prominent mechanisms contributing to energy dissipation in nacre. The biopolymer spacing between the nanograins facilitates the grain rotation process. The aragonite nanograins in nacre are not brittle but deformable.

摘要

珍珠层是一种具有卓越机械强度和韧性的天然纳米复合材料。纳米级结构在珍珠层的非弹性和增韧过程中发挥着什么作用？我们能否从中获得启发来制备类似珍珠层的纳米复合材料？在此，我们报告了对平均晶粒尺寸为32纳米的文石纳米晶粒（纳米颗粒）构成的珍珠层进行的原位动态原子力显微镜观察，结果表明纳米晶粒的旋转和变形是珍珠层中能量耗散的两个主要机制。纳米晶粒之间的生物聚合物间距促进了晶粒的旋转过程。珍珠层中的文石纳米晶粒并非脆性的，而是可变形的。

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珍珠层中纳米晶粒旋转与变形的原位观察。

In situ observation of nanograin rotation and deformation in nacre.

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