Fabrication and Characterization of an NBR-Based Nano Composite Shield for Protection Against Nonthermal Effects of Radar Electromagnetic Radiation

Azzazy, Ahmed El-Sayed; Ahmed, Sayed Bakri; Ahmed, Ahmed Abdel Nazir; Elmenshawy, Omar Mohamed; Abdelbaset, Yassin; Elbeih, AE.; Mostafa, H. E.; Mahmoud, M. A.

doi:10.1088/1757-899X/975/1//iccee.2025.460391

	Fabrication and Characterization of an NBR-Based Nano Composite Shield for Protection Against Nonthermal Effects of Radar Electromagnetic Radiation
The International Conference on Chemical and Environmental Engineering
Volume 13, Issue 13, October 2025, Pages 1-10 PDF (2.07 M)
Document Type: Original Article
DOI: 10.1088/1757-899X/975/1//iccee.2025.460391
Authors
Ahmed El-Sayed Azzazy^* ¹; Sayed Bakri Ahmed²; Ahmed Abdel Nazir Ahmed¹; Omar Mohamed Elmenshawy²; Yassin Abdelbaset³; AE. Elbeih⁴; H. E. Mostafa⁴; M. A. Mahmoud⁴
¹Science and technology center of excellence, Egypt.
²Faculty of Science, Al-Azhar University.
³Saqr Factory for Advanced Industries, Arab Organization for Industrialization, Egypt.
⁴Department of Chemical Engineering, Military Technical College (MTC), Cairo, Egypt.
Abstract
The increasing use of radar systems has raised concerns about the non-thermal effects of electromagnetic radiation (EMR) on biological systems, prompting the need for effective shielding solutions. This study presents a NBR-based nanocomposite shield reinforced with multi-walled carbon nanotubes (MWCNTs 2 wt.%), graphene oxide (GO), silver nanoparticles (Ag, 2 wt%), and zinc oxide nanoparticles (ZnO, 3 wt.%) as protecting agent. The composite was fabricated using a two-roll milling and compression molding process, followed by characterization via X-ray diffraction (XRD), scanning electron microscopy (SEM), and EMI Shielding Efficiency Across Frequency Range. The nanocomposite demonstrated an electromagnetic interference (SE) shielding efficiency of up to 85–90% in the X-band frequency range (1–12 GHz). This high efficiency is attributed to the synergistic absorption and reflection mechanisms facilitated by the conductive network formed by multi-walled carbon nanotubes and graphene oxide within the NBR matrix. Under simulated radar electromagnetic radiation exposure, the shield significantly reduced non-thermal effects, including oxidative stress and infertility risk, compared to unshielded samples. In addition, the composite exhibited robust mechanical properties, ensuring its suitability for practical applications in protective devices. This research highlights the potential of NBR-based nanocomposites as versatile materials for mitigating the harmful non-thermal effects of radar electromagnetic radiation. These findings pave the way for innovative advances in personal protective equipment and environmental protection technologies, providing effective solutions to address the growing concerns associated with electromagnetic radiation exposure.
Keywords
NBR-based nanocomposites; multi-walled carbon nanotubes; graphene oxide; shielding from electromagnetic interference; non-thermal effects; radar electromagnetic radiation

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