Development of metal/metal oxide enriched polymer composites for radiation shielding of low-energy photons

Increasing applications of ionizing radiation in medical and industrial processes indicate a growing demand for effective radiation shielding materials that are non-toxic and recyclable. Specific radiation–resistant, lead-free, lightweight shielding materials are required to protect personnel and patients against medical radiation since lead toxicity poses significant environmental and health risks and problems with lead utilization.

In this study 1.0 mm thick PVA polymer composite films containing 50 V/V% of different fillers (Tungsten (VI) oxide (WO₃), Tantalum (V) oxide (Ta₂O₅), Tin (Sn), and Bismuth (Bi)) were fabricated and tested for radiation attenuation performance using Multimeter Barracuda with R100B detector (RTI Electronics AB, Sweden). Irradiation of films with low energy photons was performed in X-ray therapy unit GULMAY D3225 (UK). Irradiation of samples in Leksell Gamma Knife® Icon™ (Elekta, Sweden), and linear accelerator Varian Trilogy™ (California, USA) providing MeV range photons was performed additionally for the assessment of correlations between experimental data and modeling results in the broad energy range.

Photon attenuation and shielding efficiency of fabricated experimental samples: single-filled (PVA-WO₃, PVA-Ta₂O₅, PVA-Sn, and PVA-Bi) and dual-filled (PVA-Bi-WO₃, PVA-Ta₂O₅-WO₃, PVA-Sn-WO₃, PVA-Bi-Ta₂O₅, PVA-Sn-Ta₂O₅, PVA-Bi-Sn) polymer composites were assessed using experimental measurements data. Experimental results were verified against simulation data obtained using open-access software Phy-X/PSD and compared with the data corresponding to 0.25 and 0.5 mmPb lead equivalent as reference of required medical radiation shielding equipment.

It was shown that single filler PVA-Bi and dual-filler with WO₃–Bi composites exhibited the highest radiation shielding efficiency in the low energy range and at certain energies were performing better than 0.25 mm Pb equivalency, indicating composites‘ potential to be explored in lead-free, lightweight, low-toxicity medical radiation shielding equipment.

Obtained results suggest that PVA-metal/metal oxide composites, especially those with bismuth and tungsten, are promising candidates for environmentally sustainable radiation shielding.