Epoxy composites filled with boron nitride and aluminum nitride for improved thermal conductivity

J. M. Hutchinson; F. Román; P. Cortés; Y. Calventus

doi:10.14314/polimery.2017.560

Published : 2021-01-15

Vol. 62 No. 7-8 (2017)

Epoxy composites filled with boron nitride and aluminum nitride for improved thermal conductivity

J. M. Hutchinson F. Román P. Cortés Y. Calventus

DOI: https://doi.org/10.14314/polimery.2017.560

Abstract

Epoxy composites containing boron nitride (BN) or aluminum nitride (AlN or Al₂N₃) particles have been studied with a view to obtaining increased thermal conductivity. The effect of these fillers on the cure reaction has been investigated by differential scanning calorimetry (DSC) for two systems, epoxy-diamine and epoxy-thiol, and for volume fractions up to about 35 % of these filler particles. For the epoxy-diamine system, the glass transition temperature of the fully cured system, the heat of reaction, and the temperature at which the peak heat flow occurs were all independent of the cure conditions, filler type and content. In contrast, the epoxy-thiol system shows a systematic effect of filler on the peak temperature for both fillers: there is an initial acceleration of the reaction, which diminishes with increasing content, and the reaction is even significantly retarded at high contents for BN. This is interpreted in terms of an improved interface between epoxy matrix and particles, with a consequent enhancement of the thermal conductivity of the epoxy-thiol composites.

Keywords

epoxy composites ; boron nitride ; aluminum nitride ; thermal conductivity ; differential scanning calorimetry kompozyty epoksydowe ; azotek boru ; azotek aluminium ; przewodność cieplna ; różnicowa kalorymetria skaningowa

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Hutchinson, J. M., Román, F., Cortés, P., & Calventus, Y. (2021). Epoxy composites filled with boron nitride and aluminum nitride for improved thermal conductivity. Polimery, 62(7-8), 560-566. https://doi.org/10.14314/polimery.2017.560

References

Crossref (access date 06.10.2016).

[2]
Crossref (access date 06.10.2016).

[3] Xu Y.S., Chung D.D.L., Mroz C.: Composites Part A: Applied Science and Manufacturing 2001, 32, 1749.
Crossref

[4] Lee G-W., Park M., Kim J. et al.: Composites Part A: Applied Science and Manufacturing 2006, 37, 727.
Crossref

[5] Yung K.C., Liem H.: Journal of Applied Polymer Science 2007, 106, 3587.
Crossref

[6] Shimazaki Y., Hojo F., Takezawa Y.: Applied Physics Letters 2008, 92, 133 309.
Crossref

[7] Hong J-P., Yoon S-W., Hwang T. et al.: Thermochimica Acta 2012, 537, 70.
Crossref

[8] Choi S., Kim J.: Composites Part B: Engineering 2013, 51, 140.
Crossref

[9] Xu Y., Chung D.D.L.: Composite Interfaces 2000, 7, 243.
Crossref

[10] Wattanakul K., Manuspiya H., Yanumet N.: Journal of Applied Polymer Science 2011, 119, 3234.
Crossref

[11] Ji T., Zhang L.Q., Wang W.C. et al.: Polymer Composites 2012, 33, 1473.
Crossref

[12] Song W-L., Wang P., Cao L. et al.: Angewandte Chemie International Edition 2012, 51, 6498.
Crossref

[13] Moses J.E., Moorhouse A.D.: Chemical Society Reviews 2007, 36, 1249.
Crossref

[14] Flores M., Tomuta A.M., Fernández-Francos X. et al.: Polymer 2013, 54, 5473.
Crossref

[15] Carlborg C.F., Vastesson A., Liu Y. et al.: Journal of Polymer Science Part A: Polymer Chemistry 2014, 52, 2604.
Crossref

[16] Hammerschmidt U., Meier V.: International Journal of Thermophysics 2006, 27, 840.
Crossref

[17] Yu J., Huang X., Wu C. et al.: Polymer 2012, 53, 471.
Crossref

[18] Gu J., Zhang Q., Dang J., Xie C.: Polymers for Advanced Technologies 2012, 23, 1025.
Crossref

[19] Hong J-P., Yoon, S-W., Hwang T-S. et al.: Korea-Australia Rheology Journal 2010, 22, 259.

[20] Kim K., Kim M., Hwang Y., Kim J.: Ceramics International 2014, 40, 2047.
Crossref

[21] Kim K., Kim J.: Ceramics International 2014, 40, 5181.
Crossref

[22] Wang Z., Iizuka T., Kozako M. et al.: IEEE Transactions on Dielectrics and Electrical Insulation 2011, 18, 1963.
Crossref

[23] Gaska K., Rybak A., Kapusta C. et al.: Polymers for Advanced Technologies 2015, 26, 26.
Crossref

[24] Duwe S., Arlt C., Aranda S. et al.: Composites Science and Technology 2012, 72, 1324.
Crossref

[25] Zhu B.L., Wang J., Ma J. et al.: Journal of Applied Polymer Science 2012, 127, 3456.
Crossref

[26] Rybak A., Gaska K.: Journal of Materials Science 2015, 50, 7779.
Crossref

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J. M. Hutchinson hutchinson@mmt.upc.edu

Affiliation
Escola Superior d’Enginyeries Industrial, Aeroespacial i Audiovisual de Terrassa C/ Colom 11, 08222 Terrassa, Spain

F. Román

Affiliation
Escola Superior d’Enginyeries Industrial, Aeroespacial i Audiovisual de Terrassa C/ Colom 11, 08222 Terrassa, Spain

P. Cortés

Affiliation
Escola Superior d’Enginyeries Industrial, Aeroespacial i Audiovisual de Terrassa C/ Colom 11, 08222 Terrassa, Spain

Y. Calventus

Affiliation
Escola Superior d’Enginyeries Industrial, Aeroespacial i Audiovisual de Terrassa C/ Colom 11, 08222 Terrassa, Spain