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Main Authors: Worden, Henry, Chandra, Mihir, Zhou, Yijie, Bhuiyan, Zarif Ahmad Razin, Cheng, Mouyang, Munusamy, Krishnamurthy, Hu, Weiguo, Yan, Weibo, Wu, Siyu, Li, Ruipeng, Chatterji, Anna, Emrick, Todd, Liu, Jun, Xu, Yanfei
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.12124
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author Worden, Henry
Chandra, Mihir
Zhou, Yijie
Bhuiyan, Zarif Ahmad Razin
Cheng, Mouyang
Munusamy, Krishnamurthy
Hu, Weiguo
Yan, Weibo
Wu, Siyu
Li, Ruipeng
Chatterji, Anna
Emrick, Todd
Liu, Jun
Xu, Yanfei
author_facet Worden, Henry
Chandra, Mihir
Zhou, Yijie
Bhuiyan, Zarif Ahmad Razin
Cheng, Mouyang
Munusamy, Krishnamurthy
Hu, Weiguo
Yan, Weibo
Wu, Siyu
Li, Ruipeng
Chatterji, Anna
Emrick, Todd
Liu, Jun
Xu, Yanfei
contents This study presents a new strategy for achieving ultralow thermal conductivity in nonporous polymer/organic filler hybrids by suppressing heat capacity through tailored atomic vibrations to enhance thermal insulation. Unlike conventional polymer/inorganic filler hybrids, these hybrids exhibit interfacial thermal resistance one to three orders of magnitude lower. Combined experiments and simulations uncover thermal transport mechanisms. These hybrids demonstrate enhanced flame retardancy. Please see the abstract in the attached PDF.
format Preprint
id arxiv_https___arxiv_org_abs_2510_12124
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Engineering Nonporous Polymer Hybrids with Suppressed Heat Conduction and Enhanced Flame Retardancy via Molecular and Filler Design
Worden, Henry
Chandra, Mihir
Zhou, Yijie
Bhuiyan, Zarif Ahmad Razin
Cheng, Mouyang
Munusamy, Krishnamurthy
Hu, Weiguo
Yan, Weibo
Wu, Siyu
Li, Ruipeng
Chatterji, Anna
Emrick, Todd
Liu, Jun
Xu, Yanfei
Applied Physics
This study presents a new strategy for achieving ultralow thermal conductivity in nonporous polymer/organic filler hybrids by suppressing heat capacity through tailored atomic vibrations to enhance thermal insulation. Unlike conventional polymer/inorganic filler hybrids, these hybrids exhibit interfacial thermal resistance one to three orders of magnitude lower. Combined experiments and simulations uncover thermal transport mechanisms. These hybrids demonstrate enhanced flame retardancy. Please see the abstract in the attached PDF.
title Engineering Nonporous Polymer Hybrids with Suppressed Heat Conduction and Enhanced Flame Retardancy via Molecular and Filler Design
topic Applied Physics
url https://arxiv.org/abs/2510.12124