Characterization of Epoxy/Fe₂O₃ Nanocomposites with Enhanced Physical Properties

Authors

  • Ali Sallal Department of Physics, College of Science, University of Diyala, 32001, Iraq
  • Sarah M. Abdallh Department of Physics, College of Science, University of Diyala, 32001, Iraq
  • Shahad A. Nayef Department of Physics, College of Science, University of Diyala, 32001, Iraq

DOI:

https://doi.org/10.26554/ijmr.20264183

Keywords:

Structural Properties, Thermal Properties, Dielectric Properties, Epoxy, Nanocomposite, Iron Oxide (Fe₂O₃)

Abstract

In this study, epoxy/iron oxide (EP/Fe₂O₃) nanocomposites were prepared at different weight percentages (0.1, 0.3, and 0.5 wt%) to investigate their structural, thermal, electrical, dielectric, and mechanical properties. Scanning electron microscopy (SEM) images showed that the Fe₂O₃ nanoparticles possessed a homogeneous morphology with irregular grain size and an average size of 60–70 nm, indicating their suitability for reinforcing polymer matrices. The addition of Fe₂O₃ nanoparticles significantly improved the thermal conductivity of the epoxy due to the formation of partial phonon transport pathways and enhanced interfacial interaction at higher addition percentages. Dielectric measurements showed an increase in the dielectric constant and dielectric loss with increasing Fe₂O₃ content, with both decreasing with increasing frequency due to interfacial polarization mechanisms. AC electrical conductivity results demonstrated frequency-dependent behavior with a marked improvement in conductivity upon nanoparticle addition. Furthermore, the Shore D hardness test results showed a gradual improvement with increasing Fe₂O₃ content, attributed to the restriction of epoxy chain movement and increased cross-linking density. These results confirm that Fe₂O₃ is an effective filler for enhancing the performance of multifunctional epoxy composites.

References

Abdeen, D. H., M. El Hachach, M. Koc, and M. A. Atieh (2019). A Review on the Corrosion Behaviour of Nanocoatings on Metallic Substrates. Materials, 12(2); 210.

Balguri, P. K., D. G. H. Samuel, and U. Thumu (2021). A Review of the Mechanical Properties of Epoxy Nanocomposites. Materials Today: Proceedings, 44; 346–355.

Campo, M., O. Redondo, and S. G. Prolongo (2020). Barrier Properties of Thermal and Electrical Conductive Hydrophobic Multigraphitic/Epoxy Coatings. Journal of Applied Polymer Science, 137(42); 49281.

Chen, J., L. Yan, W. Song, and D. Xu (2018). Interfacial Characteristics of Carbon Nanotube–Polymer Composites: A Review. Composites Part A: Applied Science and Manufacturing, 114; 149–169.

de Oliveira, J. B., L. M. Guerrini, L. d. S. Conejo, M. C. Rezende, and E. C. Botelho (2019). Viscoelastic Evaluation of Epoxy Nanocomposite Based on Carbon Nanofiber Obtained from Electrospinning Processing. Polymer Bulletin, 76; 6063–6076.

Frigione, M. and M. Lettieri (2020). Recent Advances and Trends of Nanofilled/Nanostructured Epoxies. Materials, 13(15); 3415.

Glaskova-Kuzmina, T., A. Aniskevich, A. Zotti, and A. Borriello (2020). Flexural Properties of Epoxy Resin Filled with Single and Hybrid Carbon Nanofillers. Journal of Physics: Conference Series, 1545; 012001.

Hajiyeva, F. V. and M. A. Ramazanov (2025). Effect of Zirconium Oxide Nanoparticles on Structure, Dielectric, and Optical Properties of PVDF/Zirconia-Based Nanocomposites. International Journal of Modern Physics B, 39(2); 2550020.

Hardiman, M., T. J. Vaughan, and C. T. McCarthy (2015). Fibrous Composite Matrix Characterisation Using Nanoindentation: The Effect of Fibre Constraint and the Evolution from Bulk to In-Situ Matrix Properties. Composites Part A: Applied Science and Manufacturing, 68; 296–303.

Jing, Y., Y. Wang, D. Zhang, T. Wang, Y. Liu, and J. Zhang (2020). Molybdenum Disulfide with Poly(dopamine) and Epoxy Groups as an Efficient Anticorrosive Reinforcement in Epoxy Coating. Synthetic Metals, 259; 116249.

Kaminsky, W. (2018). Polyolefin-Nanocomposites with Special Properties by In-Situ Polymerization. Frontiers of Chemical Science and Engineering, 12(3); 555–563.

Kausar, A. (2020). Performance of Corrosion Protective Epoxy Blend-Based Nanocomposite Coatings: A Review. Polymer-Plastics Technology and Materials, 59(6); 658–673.

Luo, X., G. Yang, and D. W. Schubert (2022). Electrically Conductive Polymer Composite Containing Hybrid Graphene Nanoplatelets and Carbon Nanotubes: Synergistic Effect and Tunable Conductivity Anisotropy. Advanced Composites and Hybrid Materials, 5(1); 250–262.

Mohammed, M. I. (2022). Dielectric Dispersion and Relaxations in (PMMA/PVDF)/ZnO Nanocomposites. Polymer Bulletin, 79(4); 2443–2459.

Najmi, L. and Z. Hu (2023). Effects of Carbon Nanotubes on Thermal Behavior of Epoxy Resin Composites. Journal of Composites Science, 7(8); 313.

Prakash, V. A. and A. Rajadurai (2016). Mechanical, Thermal and Dielectric Characterization of Iron Oxide Particles Dispersed Glass Fiber Epoxy Resin Hybrid Composite. Digest Journal of Nanomaterials and Biostructures, 11(2); 373–380.

Saharudin, M. S. and F. Inam (2020). Flexural Properties of Halloysite Nanotubes and Carbon Nanotubes Toughened Epoxy Composites. International Journal of Innovative Technology and Exploring Engineering, 9; 1670–1675.

Sahu, M., A. K. Bhowmick, S. Shenoy, and S. Bose (2017). Noncovalently Functionalized Tungsten Disulfide Nanosheets for Enhanced Mechanical and Thermal Properties of Epoxy Nanocomposites. ACS Applied Materials & Interfaces, 9(16); 14347–14357.

Sanli, A., M. Morshed, and S. Van Hoa (2016). Piezoresistive Characterization of Multi-Walled Carbon Nanotube–Epoxy-Based Flexible Strain-Sensitive Films by Impedance Spectroscopy. Composites Science and Technology, 122; 18–26.

Spinelli, G., P. Lamberti, V. Tucci, L. Vertuccio, and L. Guadagno (2020). Damage Monitoring of Structural Resins Loaded with Carbon Fillers: Experimental and Theoretical Study. Nanomaterials, 10(3); 434.

Subadra, S. P., R. Babu, S. Senthilvelan, and B. N. Raghunandan (2020). High-Performance Fiberglass/Epoxy Reinforced by Functionalized CNTs for Vehicle Applications with Less Fuel Consumption and Greenhouse Gas Emissions. Polymer Testing, 86; 106480.

Wang, Z., G. Wu, X. Zhang, K. Yang, Y. Wang, and W. Zhou (2017). Sandwiched Epoxy-Alumina Composites with Synergistically Enhanced Thermal Conductivity and Breakdown Strength. Journal of Materials Science, 52; 4299–4308.

Wei, J., M. S. Saharudin, T. Vo, and F. Inam (2017a). Dichlorobenzene: An Effective Solvent for Epoxy/Graphene Nanocomposites Preparation. Royal Society Open Science, 4(10); 170778.

Wei, J., M. S. Saharudin, T. Vo, and F. Inam (2017b). N,N-Dimethylformamide (DMF) Usage in Epoxy/Graphene Nanocomposites: Problems Associated with Reaggregation. Polymers, 9(6); 193.

Wu, Y., X. Zhang, A. Negi, J. He, G. Hu, S. Tian, and J. Liu (2020). Synergistic Effects of Boron Nitride (BN) Nanosheets and Silver (Ag) Nanoparticles on Thermal Conductivity and Electrical Properties of Epoxy Nanocomposites. Polymers, 12(2); 426.

Yıldırım, F., N. Ataberk, and M. Ekrem (2021). Mechanical and Thermal Properties of Epoxy-Based Nanocomposites Reinforced with Polyvinyl Alcohol Nanofibers Containing Multiwalled Carbon Nanotubes. Journal of Composite Materials, 55(10); 1339–1347.

Yuan, Y., Y. Zhang, J. Liu, H. Wang, Q. Chen, and Z. Li (2020). Reversible Nonlinear I–V Behavior of ZnO-Decorated Graphene Nanoplatelets/Epoxy Resin Composites. Polymers, 12(4); 951.

Downloads

Published

2026-02-28

Issue

Vol. 4 No. 1 (2026): March

Section

Articles