材料科学
热导率
层状结构
散射
导电体
电介质
纳米尺度
聚合物
热的
热传导
凝聚态物理
复合材料
曲面(拓扑)
堆栈(抽象数据类型)
传热
Crystal(编程语言)
电导率
各向异性
聚乙烯
边值问题
单晶
热导率测量
聚合物结晶
化学物理
自组装
纳米技术
作者
Min Chen,Ting Yu,Jing Tu,Jie Yang,Xia Guo,Ruiyi Li,Tao Chen,Ye Zhu,David G. Cahill,Hanying Li,Wee‐Liat Ong
标识
DOI:10.1002/adma.202520085
摘要
Polymer lamellar crystals with highly ordered crystalline structures are ideal systems for understanding and engineering thermally conductive polymers. However, their nanometer-scale thickness, hard-to-eliminate defects, and limited lateral dimensions have impeded experimental characterization, leaving key thermal transport mechanisms unresolved. Here, we address this knowledge gap by devising a multilayer single-crystal stack for a non-contact measurement technique, combined with advanced theoretical calculations. The measured cross-plane thermal conductivity is 4 W m-1 K-1 for a 12-nm-thick polyethylene lamellar single crystal, representing the highest value observed for dielectric materials in this thickness range. Theoretical analyses indicate that this value is nevertheless limited by the combined effects from boundary scattering and surface amorphization, offering critical insights for molecular design and understanding of nanoscale heat transfer in ultrathin soft materials.
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