生物
机械能
复合数
振动
弹性能
材料科学
变形(气象学)
智能材料
机械系统
模数
纳米技术
复合材料
物理
机械工程
声学
工程类
考古
功率(物理)
历史
量子力学
自然(考古学)
作者
Xiang Wang,Zhihao Li,Shuxu Wang,Koki Sano,Zhifang Sun,Zhenhua Shao,Asuka Takeishi,Seishiro Matsubara,Dai OKUMURA,Nobuyuki Sakai,Takayoshi Sasaki,Takuzo Aida,Yasuhiro Ishida
出处
期刊:Science
[American Association for the Advancement of Science]
日期:2023-04-13
卷期号:380 (6641): 192-198
被引量:73
标识
DOI:10.1126/science.adf1206
摘要
Mechanical nonreciprocity, or the asymmetric transmission of mechanical quantities between two points in space, is crucial for developing systems that can guide, damp, and control mechanical energy. We report a uniform composite hydrogel that displays substantial mechanical nonreciprocity, owing to direction-dependent buckling of embedded nanofillers. This material exhibits an elastic modulus more than 60 times higher when sheared in one direction compared with the opposite direction. Consequently, it can transform symmetric vibrations into asymmetric ones that are applicable for mass transport and energy harvest. Furthermore, it exhibits an asymmetric deformation when subjected to local interactions, which can induce directional motion of various objects, including macroscopic objects and even small living creatures. This material could promote the development of nonreciprocal systems for practical applications such as energy conversion and biological manipulation.
科研通智能强力驱动
Strongly Powered by AbleSci AI