材料科学
纤维
DNA超螺旋
DNA
储能
纳米技术
复合材料
化学物理
热力学
物理
遗传学
DNA复制
生物
功率(物理)
作者
Ziyu Zhao,Jiarui Yang,Wenrui Cai,Guojiang Wen,Zhiwei Zhu,Zheng‐Ying Liu,Xuewei Fu,Zhiqiang Cao,Zunfeng Liu,Wei Yang,Yu Wang
标识
DOI:10.1002/adma.202503330
摘要
Abstract The conformational folding/unfolding behaviors of DNA supercoils serve as a fundamental mechanism governing ultradense bio‐information storage and precise genetic transcription. Mimicking those nanoscale dynamic conformational behaviors for macroscopic materials to achieve unusual functionalities will be of great interest but remains unexplored. Herein, a DNA‐inspired materials evolution paradigm is presented to create multifunctional supercoiled conformational fibers (SCFs) by programmed twisting controlled self‐buckling. Through the programmed twist‐stress modulation, a low‐density polyethylene strip is transformed into high‐performance DNA‐like SCF through a unique multiscale microstructure evolution process. This DNA‐like SCF exhibits five hallmark characteristics unattainable before, including ultra‐large elastic deformability (900 ± 50%), metal‐level mechanical strength (330 ± 30 MPa), unprecedented torsional energy‐storage density (16.1 ± 0.6 kJ kg −1 ), torsional energy release upon appropriate stimulations, and impact buffering through conformation‐mediated energy‐dissipation. Characterization reveals that these unexpected energy‐related properties mainly are contributed by the multiscale twisting‐reinforced microstructures and conformation mechanics. Potential applications of the SCFs are demonstrated finally by harvest‐and‐storage of wind energy and soft‐landing. The DNA‐like SCFs indicate a general platform for materials evolution with extraordinary mechanics and functions.
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