Journal of Materiomics

Journal of Materiomics

Volume 8, Issue 5, September 2022, Pages 1058-1066
Journal of Materiomics

Research paper
Particle packing theory guided multiscale alumina filled epoxy resin with excellent thermal and dielectric performances

https://doi.org/10.1016/j.jmat.2022.02.008Get rights and content
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open access

Highlights

  • Particle packing theory is utilized to guide multiscale thermal conductive particles filling epoxy resin.

  • The optimized multiscale alumina filled epoxy resin displays a remarkably improved thermal conductivity of 2.707 W m−1 K−1.

  • The thermal conduction paths could be effectively formed by appropriate multiscale fillers.

  • The addition of multiscale alumina leads to the increase of dielectric constant of composites.

Abstract

Polymers and composites with high thermal conductivity are promising yet challenging for the growing demand of thermal management in electrical and electronic equipment. Guided by the closest packing model, a multiscale filling Al2O3 strategy was designed and incorporated with epoxy resin (EP) to form high thermal conductive composites in this work. Epoxy composites with single filler loading were also prepared. The microstructures, thermal, rheological, and dielectric characteristics of the multiscale filling Al2O3/EP composites have been investigated. Compared with single-scale Al2O3 filled epoxy based composites, it is found that the multiscale filling Al2O3/EP composites exhibit higher thermal conductivity under the same filler loading of 50 vol %, which is attributed to the efficient heat conduction paths formed by appropriate multiscale fillers. Particularly, a remarkably improved thermal conductivity of 2.707 W m−1 K−1 was acquired in Al2O3/EP composites at filler loading of 50 vol% (5 μm Al2O3 (26.67 vol%), 30 μm Al2O3 (27.41 vol%) and 70 μm Al2O3 (45.92 vol%)), which is about 1300% higher than that of the pure epoxy resin. In addition, the dielectric constant of the Al2O3/EP composites were significantly improved while keeping the dielectric loss almost unchanged. The finite element simulation further verified the effectiveness of improving the thermal conductivity of materials in the heat dissipation of electrical equipment. Therefore, this research provides a simple strategy for manufacturing high thermal conductive composite materials with a wide range of potential applications as packaging materials.

Keywords

Closest packing model
Epoxy composites
Alumina
Thermal conductivity
Dielectric property

Cited by (0)

Qi-Kun Feng received his master's degree from North China Electric Power University in 2019 and is currently pursuing the Ph.D. degree under the supervision of Professor Zhi-Min Dang at Department of Electrical Engineering, Tsinghua University. His research interest is focused on dielectric materials for energy storage and insulating material with high thermal conductivity.

Zhi-Min Dang received his Ph.D. degree in Electrical Engineering from Xi'an Jiaotong University in 2001. He is currently a Professor in Department of Electrical Engineering, Tsinghua University. His research interests are in the field of Advanced Energy/Electrical Materials and Devices, especially for Polymer Dielectrics for Energy Storage. He has published more than 300 journal papers with a current citation record of over 13000 times and an H-index of 64. He has also published 7 Scientific Books as Editor or Co-Editor. He was elected a Fellow of the Institution of Engineering and Technology (IET), serves as the editor-in-chief of an International Journal of IET Nanodielectrics, and is an international board member for several journals. Recently, he was become one of the world's top 100000 scientists ranked No. 5113.

Peer review under responsibility of The Chinese Ceramic Society.

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Qi-Kun Feng and Chang Liu contributed equally to this work.

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