Decoding Thermal Properties in Polymer-Inorganic Heat Dissipators: A Data-Driven Approach Using Pyrolysis Mass Spectrometry

Yusuke Hibi; Yasuhiro Tsuyuki; Satoshi Ishii; Eiichi Ide; Masanobu Naito

doi:10.1080/14686996.2024.2362125

論文 Decoding Thermal Properties in Polymer-Inorganic Heat Dissipators: A Data-Driven Approach Using Pyrolysis Mass Spectrometry

Yusuke Hibi (Research Center for Macromolecules and Biomaterials/Macromolecules Field/Data-driven Polymer Design Group, National Institute for Materials Science) ; Yasuhiro Tsuyuki (Hitachi, Ltd) ; Satoshi Ishii (Hitachi, Ltd) ; Eiichi Ide (Hitachi, Ltd) ; Masanobu Naito (Research Center for Macromolecules and Biomaterials/Macromolecules Field/Data-driven Polymer Design Group, National Institute for Materials Science)

Decoding thermal properties in polymer-inorganic heat dissipators a data-driven approach using pyrolysis mass spectrometry.pdf

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Yusuke Hibi, Yasuhiro Tsuyuki, Satoshi Ishii, Eiichi Ide, Masanobu Naito. Decoding Thermal Properties in Polymer-Inorganic Heat Dissipators: A Data-Driven Approach Using Pyrolysis Mass Spectrometry. Science and Technology of Advanced Materials. 2024, 25 (1), . https://doi.org/10.1080/14686996.2024.2362125

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(abstract)

Polymeric materials can boost their performances by strategically incorporating inorganic substances. Heat dissipators are a representative class of such composite materials, where inorganic fillers and matrix polymers contribute to high thermal conductivity and strong adhesion, respectively, resulting in excellent heat dissipation performance. However, due to the complex interaction between fillers and polymers, even slight differences in structural parameters, e.g., dispersion/aggregation degree of fillers and crosslink density of polymers, may significantly impact material performance, complicating the quality management and guidelines for material developments. Therefore, we introduce pyrolysis mass spectra (MS) as material descriptors. On the basis of these spectra, we construct prediction models using a data-driven approach, specifically focusing on thermal conductivity and adhesion, which are key indicators for heat dissipating performance. Pyrolysis-MS observes thermally decomposable polymers, which occupy only 0.1 volume fraction of the heat dissipators; nevertheless, the physical states of non-decomposable inorganic fillers are implicitly reflected in the pyrolyzed fragment patterns of the matrix polymers. Consequently, pyrolysis-MS provides sufficient information to construct accurate models for predicting heat dissipation performance, simplifying quality management by substituting time-consuming performance evaluations with rapid pyrolysis-MS measurements. Furthermore, we elucidate that higher crosslinking density of the matrix polymers enhances thermal conductivity. This data-driven method promises to streamline the identification of key functional factors in complex composite materials.

権利情報:

Creative Commons BY Attribution 4.0 International

キーワード: Composite material, heat conductivity, pyrolysis mass spectrometry, non-negative matrix factorization

刊行年月日: 2024-12-31

出版者: Taylor & Francis

掲載誌:

Science and Technology of Advanced Materials (ISSN: 14686996) vol. 25 issue. 1

研究助成金:

JSPS JSPS KAKENHI Grant NumberJP24K08520
JST Core Research for EvolutionalScience and Technology program of Japan Science andTechnology Agency under Grant JPMJCR19J3

原稿種別: 出版者版 (Version of record)

MDR DOI:

公開URL: https://doi.org/10.1080/14686996.2024.2362125

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更新時刻: 2024-06-19 15:18:48 +0900

MDRでの公開時刻: 2024-06-14 16:30:16 +0900

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