Litcius/Paper detail

Layered structural engineering of Bi2O3/PP and WO3/PP composites for γ-ray shielding in high energy range: anisotropic attenuation mechanisms via Monte Carlo simulation and experiments

Xiangjie Duan, Jie Zhao, Shuaida Song, N. Zhou, Jizhuang Fan, Bo Tian, Yunchen Du

2025Journal of Materials Research and Technology11 citationsDOIOpen Access PDF

Abstract

The development of non-toxic and flexible polymer-based shielding composites has become a research hotspot due to the severe harm of γ ray to living organisms, mechanical equipment, and the environment. However, the γ-ray shielding performance of polymer-based composites in the high-energy range remains unsatisfactory. Herein, FLUKA Monte Carlo simulations capable of visualizing γ-photon transport behaviors are investigated in Bi 2 O 3 /PP and WO 3 /PP multi-layer composites with various layered configurations. The simulation results reveal significant anisotropic attenuation effects on shielding characteristics caused by the layered structure and the incident path of γ-photons relative to the interface position. Subsequently, single-layer, AB, and sandwich-like ABA composites with a fixed thickness of 2.0 mm are experimentally fabricated via melt-mixing and hot press methods. At 1332 keV, sandwich-like WPPBPPWPP composite (WO 3 /PP outer layers + Bi 2 O 3 /PP core) achieves linear attenuation coefficients and radiation protection efficiency of 0.31 cm -1 and 6%, respectively, which are 29% higher than those of single-layer composite. These improvements originate from the multiple scattering induced by interlayer interface. Additionally, layered configurations with externally placed high-density fillers (WO 3 ) and internally placed high atomic number fillers (Bi 2 O 3 ) further promote γ-photon attenuation in high-energy range. Experimental results validate the anisotropic shielding trends observed in MC simulations. Moreover, multi-layer composites demonstrate significantly improved energy storage capacity, thermal stability, and oxidation resistance while maintaining comparable to those of single-layer composites. This work provides a scalable strategy for developing non-toxic and flexible shielding materials applicable in nuclear protection, medical devices, and aerospace systems, where lightweight and efficient radiation attenuation are critical.

Topics & Concepts

Materials scienceElectromagnetic shieldingAttenuationAnisotropyMonte Carlo methodComposite materialRange (aeronautics)OpticsPhysicsMathematicsStatisticsRadiation Shielding Materials AnalysisGraphite, nuclear technology, radiation studiesNuclear Physics and Applications