Enhancement of Ceramics Based Red-Clay by Bulk and Nano Metal Oxides for Photon Shielding Features

We prepared red clays by introducing different percentages of PbO, Bi(2)O(3), and CdO. In order to understand how the introduction of these oxides into red clay influences its attenuation ability, the mass attenuation coefficient of the clays was experimentally measured in a lab using an HPGe detector. The theoretical shielding capability of the material present was obtained using XCOM to verify the accuracy of the experimental results. We found that the experimental and theoretical values agree to a very high degree of precision. The effective atomic number (Z(eff)) of pure red clay, and red clay with the three metal oxides was determined. The pure red clay had the lowest Z(eff) of the tested samples, which means that introducing any of these three oxides into the clay will greatly enhance its Z(eff), and consequently its attenuation capability. Additionally, the Z(eff) for red clay with 10 wt% CdO is lower than the Z(eff) of red clay with 10 wt% Bi(2)O(3) and PbO. We also prepared red clay using 10 wt% CdO nanoparticles and compared its attenuation ability with the red clay prepared with 10 wt% PbO, Bi(2)O(3), and CdO microparticles. We found that the MAC of the red clay with 10 wt% nano-CdO was higher than the MAC of the clay with microparticle samples. Accordingly, nanoparticles could be a useful way to enhance the shielding ability of current radiation shielding materials.