热传导
热导率
材料科学
纳米复合材料
热的
聚合物
聚合物纳米复合材料
小型化
碳纳米管
纳米技术
环氧树脂
保温
传热
复合材料
数码产品
热流密度
柔性电子器件
热桥
复合数
热阻
热接触电导
石墨烯
工作(物理)
散热膏
导电聚合物
散热片
表面改性
导电体
电子包装
热扩散率
热发射率
界面热阻
作者
Sicheng Zhang,Xiao‐Hang Lu,Liu Ji,Jing Wu,Xiaolong Jia,Bin Sun,Chao Gao,Xiaofeng Li,Zhong‐Zhen Yu
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-10-08
卷期号:19 (41): 36663-36674
被引量:14
标识
DOI:10.1021/acsnano.5c12250
摘要
The rapid miniaturization and integration of modern electronics have intensified heat generation, creating an urgent demand for high-performance thermal interfacial materials (TIMs). Although constructing oriented thermal conduction networks in polymer composites is effective in achieving high through-plane thermal conductivity for TIM applications, conventional approaches often involve harsh processing and overlook limitations in the overall heat flux, hindering further breakthroughs in thermal conduction performances. Herein, inspired by the transpiration process in bamboo, we design a biomimetic “bamboo stem array-leaf” thermal conduction network using a mild noncovalent functionalization and hierarchical structural assembly strategy. In this design, vertically aligned polydopamine-functionalized pitch-based carbon fibers (mPCFs) act as “stems” for primary heat conduction, while polyamide epichlorohydrin-modified graphene nanoplatelets self-assemble onto the mPCFs, serving as “leaves” to enhance horizontal heat diffusion. This bioinspired network synergistically integrates efficient long-range heat transport with enhanced interfacial thermal coupling with the polymer matrix, boosting the overall heat flux across the composite. The resultant epoxy composite achieves an exceptional through-plane thermal conductivity of 289.5 W m –1 K –1, surpassing most polymer composites and even certain metals. Moreover, the underlying thermal conduction mechanisms are clarified by correlating experimental results with predictions from classical models and finite element simulations. This work establishes an alternative paradigm for developing high-performance polymer nanocomposites with metal-like thermal conductivity for advanced TIM applications.
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