材料科学
执行机构
磁性纳米粒子
纳米颗粒
自愈水凝胶
纳米技术
聚合物
人工肌肉
弹性体
复合材料
弹性(物理)
力密度
磁场
机械
计算机科学
高分子化学
物理
人工智能
量子力学
作者
Roland Fuhrer,Evagelos K. Athanassiou,Norman A. Luechinger,Wendelin J. Stark
出处
期刊:Small
[Wiley]
日期:2009-01-29
卷期号:5 (3): 383-388
被引量:296
标识
DOI:10.1002/smll.200801091
摘要
The combination of force and flexibility is at the core of biomechanics and enables virtually all body movements in living organisms. In sharp contrast, presently used machines are based on rigid, linear (cylinders) or circular (rotator in an electrical engine) geometries. As a potential bioinspired alternative, magnetic elastomers can be realized through dispersion of micro- or nanoparticles in polymer matrices and have attracted significant interest as soft actuators in artificial organs, implants, and devices for controlled drug delivery. At present, magnetic particle loss and limited actuator strength have restricted the use of such materials to niche applications. We describe the direct incorporation of metal nanoparticles into the backbone of a hydrogel and application as an ultra-flexible, yet strong magnetic actuator. Covalent bonding of the particles prevents metal loss or leaching. Since metals have a far higher saturation magnetization and higher density than oxides, the resulting increased force/volume ratio afforded significantly stronger magnetic actuators with high mechanical stability, elasticity, and shape memory effect.
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