Yancheng Du, Ruixin Li, Anirudh S. Madhvacharyula, Alexander A. Swett and Jong Hyun Choi
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引用次数: 0
Abstract
Auxetic structures are unique with a negative Poisson's ratio. Unlike regular materials, they respond to external loading with simultaneous expansion or compression in all directions, rendering powerful properties advantageous in diverse applications from manufacturing to space engineering. The auxetic behaviors are determined by structural design and architecture. Such structures have been discovered in natural crystals and demonstrated synthetically with bulk materials. Recent development of DNA-based structures has pushed the unit cell size to the nanometer scale. DNA nanotechnology utilizes sequence complementarity between nucleotides. By combining sequence designs with programmable self-assembly, it is possible to construct complex structures with nanoscale accuracy and to perform dynamic reconfigurations. Herein, we report a novel design of auxetic nanostars with sliding behaviors using DNA origami. Our proposed structure, inspired by an Islamic pattern, demonstrates a unit cell with two distinct reconfigurations by programming directed sliding mechanisms. Compared to previous metamaterials, the DNA nanostars show an architecture with tunable auxetic properties for the first time. We envision that this strategy may form the basis of novel metastructures with adaptability and open new possibilities in bioengineering.
磁性结构具有独特的负泊松比。与普通材料不同,它们对外部载荷的反应是同时向各个方向膨胀或压缩,从而使其强大的性能在从制造业到航天工程的各种应用中发挥优势。辅助行为由结构设计和架构决定。这种结构已在天然晶体中被发现,并通过合成块状材料得到证实。基于 DNA 的结构的最新发展已将单位晶胞尺寸推进到纳米尺度。DNA 纳米技术利用了核苷酸之间的序列互补性。通过将序列设计与可编程自组装相结合,可以构建纳米级精度的复杂结构,并进行动态重新配置。在此,我们报告了一种利用 DNA 折纸设计的具有滑动行为的新型辅助纳米星。我们提出的结构受到伊斯兰图案的启发,通过编程定向滑动机制展示了具有两种不同重构的单元格。与之前的超材料相比,DNA 纳米星首次展示了一种具有可调辅助特性的结构。我们设想,这种策略可能会成为具有适应性的新型转移结构的基础,并为生物工程开辟新的可能性。
期刊介绍:
Molecular Systems Design & Engineering provides a hub for cutting-edge research into how understanding of molecular properties, behaviour and interactions can be used to design and assemble better materials, systems, and processes to achieve specific functions. These may have applications of technological significance and help address global challenges.
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