Abstract
Tailoring the thermal conductivity of polymers is central to enlarge their applications in the thermal management of flexible integrated circuits. Progress has been made over the past decade by fabricating materials with various nanostructures, but a clear relationship between various functional groups and thermal properties of polymers remains to be established. Here, we numerically study the thermal conductivity of single-stranded carbon-chain polymers with multiple substituents of hydrogen atoms through atomic mass modification. We find that their thermal conductivity can be tuned by atomic mass modifications as revealed through molecular dynamics simulations. The simulation results suggest that heavy homogeneous substituents do not assist heat transport and trace amounts of heavy substituents can in fact hinder heat transport substantially. Our analysis indicates that carbon chain has the biggest contribution (over 80%) to the thermal conduction in single-stranded carbon-chain polymers. We further demonstrate that atomic mass modifications influence the phonon bands of bonding carbon atoms, and the discrepancies of phonon bands between carbon atoms are responsible for the remarkable drops in thermal conductivity and large thermal resistances in carbon chains. Our study provides fundamental insight into how to tailor the thermal conductivity of polymers through variable substituents.
Highlights
There are two approaches to enhancing polymers’ thermal conductivities: dopant-based and polymer-based thermal conduction enhancement
We numerically study the thermal conductivities of single-stranded carbon-chain polymers (SCP) using equilibrium molecular dynamics (EMD) and the thermal resistances of modified single polyethylene chain (MSPEC) using classical non-equilibrium molecular dynamics (NEMD) in detail
We numerically study the thermal conductivities of single-stranded carbon-chain polymers (SCP) using adaptive intermolecular reactive empirical bond order (AIREBO) potential by EMD and the thermal resistances of modified SPEC (MSPEC) by NEMD
Summary
There are two approaches to enhancing polymers’ thermal conductivities: dopant-based and polymer-based thermal conduction enhancement. Idea is to reduce the phonon scattering sites by reducing the number of defects by fabricating polymer samples with well-aligned structures Their numerical and experimental observations of remarkably enhanced polymer thermal conductivities provided fundamental guidance on how to design and fabricate polymers with high heat transfer ability. The good agreement between mass modified cases (open squares) and real elements (solid dots) indicates that these modified masses correspond to certain elements in nature, or at least within reasonable mass range With these simplifications, our simulation results provide general insight into the fundamental mechanism of tailoring polymer thermal conductivity via atomic mass modification. Our study helps gain fundamental insight into how to improve the flexibility of controlling polymer thermal conductivity and may inspire an array of polymer-related applications
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