聚合物的导热性:简单问题复杂化

Debashish Mukherji
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引用次数: 0

摘要

导热系数 $\kappa$ 衡量材料传导热流的能力。特别是,$\kappa$ 是一个重要的属性,它通常决定了材料在各种环境条件下的有用性。例如,在热电应用中,低的$\kappa$是理想的,而在高温条件下使用材料时,则需要大的$\kappa$。这些材料的范围从普通晶体到商品无定形聚合物。后者尤其重要,因为它们可用于设计轻质高性能的功能材料。然而,在这种情况下,无定形聚合物的一个主要局限性是它们的 $k\appa 值较低,最大值约为 0.4 W/Km,比标准晶体小 2-3 个数量级。此外,当能量主要通过键合连接传递时,$k/appa 值高达 100 W/Km。最近,人们为通过大分子工程实现 $/kappa$ 的可调性做出了大量努力。在这项工作中,概述了有关聚合物和聚合物固体中 $\kappa$ 行为的最新成果。特别是在补充实验的背景下讨论了计算和理论结果。同时还强调了未来的研究方向。
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Thermal conductivity of polymers: A simple matter where complexity matters
Thermal conductivity coefficient $\kappa$ measures the ability of a material to conduct a heat current. In particular, $\kappa$ is an important property that often dictates the usefulness of a material over a wide range of environmental conditions. For example, while a low $\kappa$ is desirable for the thermoelectric applications, a large $\kappa$ is needed when a material is used under the high temperature conditions. These materials range from common crystals to commodity amorphous polymers. The latter is of particular importance because of their use in designing light weight high performance functional materials. In this context, however, one of the major limitations of the amorphous polymers is their low $\kappa$, reaching a maximum value of about 0.4 W/Km that is 2--3 orders of magnitude smaller than the standard crystals. Moreover, when energy is predominantly transferred through the bonded connections, $\kappa \ge 100$ W/Km. Recently, extensive efforts have been devoted to attain a tunability in $\kappa$ via macromolecular engineering. In this work, an overview of the recent results on the $\kappa$ behavior in polymers and polymeric solids is presented. In particular, computational and theoretical results are discussed within the context of complimentary experiments. Future directions are also highlighted.
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