An anisotropic negative thermal expansion metamaterial with sign-toggling and sign-programmable Poisson’s ratio

IF 2.9 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
T. Lim
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引用次数: 3

Abstract

A mechanical metamaterial is introduced herein by drawing inspiration from an Aztec geometric pattern. This metamaterial deformation mechanism for Poisson’s ratio and Young’s modulus is based on non-rotating rhombi with rotating triangles, and while the shear modulus analysis herein is based on rotating rhombi with non-rotating triangles, hence “partially rotating rigid units”. The coefficient of thermal expansion was obtained by equating the potential energy expressions from the simple harmonic motion and from the principle of energy equipartition, while the effective Young’s modulus was acquired by equating the strain energy from rotational stiffness with that from the strain energy of deformation from an assumed homogenised continuum. Due to the zero and extreme Poisson’s ratio based on infinitesimal deformation, the finite approach was employed. Results indicate that the proposed metamaterial exhibits anisotropic negative thermal expansion with sign-switching Poisson’s ratio when applied stress along one axis is reversed. The Poisson’s ratio for loading in another axis is undefined under tension but can be programmed to exhibit either sign when compressed. The Young’s modulus is directly governed by the rotational stiffness and strongly influenced by the extent of rotation, followed by the aspect ratio of the rotating units. Due to its uniqueness, the currently considered mechanical metamaterial can be used under specific requirements which are difficult to be attained by other materials with negative properties.
具有符号可切换和符号可编程泊松比的各向异性负热膨胀材料
本文通过从阿兹特克几何图案中汲取灵感,介绍了一种机械超材料。泊松比和杨氏模量的超材料变形机制是基于带旋转三角形的不旋转菱形,而剪切模量分析是基于带不旋转三角形的旋转菱形,因此是“部分旋转刚性单元”。热膨胀系数由简谐运动的势能表达式和能量均分原理等效得到,有效杨氏模量由旋转刚度的应变能与假设均质连续体的变形应变能等效得到。由于基于无穷小变形的泊松比为零和极值,采用了有限方法。结果表明,当外加应力沿一个轴方向反向时,所制备的超材料表现为负热膨胀,且泊松比呈符号切换。在另一个轴上加载的泊松比在张力下是未定义的,但在压缩时可以编程为显示任一符号。杨氏模量直接由旋转刚度决定,并受旋转程度的强烈影响,其次是旋转单元的长径比。由于其独特性,目前认为的机械超材料可以在特定的要求下使用,这是其他具有负性能的材料难以达到的。
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
3.60
自引率
0.00%
发文量
0
审稿时长
7 weeks
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