High Toughness Combined with High Strength in Oxide Ceramic Nanofibers

材料科学 陶瓷 纳米纤维 静电纺丝 韧性 脆性 复合材料 氧化物 极限抗拉强度 聚合物 纤维 冶金
作者
Cheng Liu,Yalong Liao,Wenling Jiao,Xiaohua Zhang,Ni Wang,Jianyong Yu,Yi‐Tao Liu,Bin Ding
出处
期刊:Advanced Materials [Wiley]
卷期号:35 (32): e2304401-e2304401 被引量:58
标识
DOI:10.1002/adma.202304401
摘要

Abstract Traditional oxide ceramics are inherently brittle and highly sensitive to defects, making them vulnerable to failure under external stress. As such, endowing these materials with high strength and high toughness simultaneously is crucial to improve their performance in most safety‐critical applications. Fibrillation of the ceramic materials and further refinement of the fiber diameter, as realized by electrospinning, are expected to achieve the transformation from brittleness to flexibility owing to the structural uniqueness. Currently, the synthesis of electrospun oxide ceramic nanofibers must rely on an organic polymer template to regulate the spinnability of the inorganic sol, whose thermal decomposition during ceramization will inevitably lead to pore defects, and seriously weaken the mechanical properties of the final nanofibers. Here, a self‐templated electrospinning strategy is proposed for the formation of oxide ceramic nanofibers without adding any organic polymer template. An example is given to show that individual silica nanofibers have an ideally homogeneous, dense, and defect‐free structure, with tensile strength as high as 1.41 GPa and toughness up to 34.29 MJ m −3 , both of which are far superior to the counterparts prepared by polymer‐templated electrospinning. This work provides a new strategy to develop oxide ceramic materials that are strong and tough.
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