<![CDATA[The use of X-rays in medical imaging provides substantial diagnostic benefits but also poses risks associated with ionizing radiation exposure. Conventional lead-based protective aprons are effective but have major limitations, including excessive weight, rigidity, and potential toxicity. This study addresses a specific research gap by systematically evaluating the relationship between material thickness, radiation attenuation effectiveness, and the Half-Value Layer (HVL) of silicone rubber-based aprons filled with lead(II) oxide (PbO) at clinically relevant low-to-medium X-ray energies. An experimental method was employed by fabricating silicone–PbO composite apron prototypes with three thickness variations (2.5 mm, 3.0 mm, and 3.5 mm). Radiation attenuation tests were conducted at X-ray tube voltages of 60, 65, and 70 kV by measuring radiation intensity before and after transmission through the samples using a radiation detector, followed by calculating protection effectiveness and HVL values. The results demonstrate that apron thickness significantly influences radiation protection performance, with the highest attenuation of 85.11% achieved at a thickness of 3.5 mm. A moderate-to-strong positive correlation between thickness and protection effectiveness is observed at all voltage levels, with the highest coefficient of determination (R² = 0.916) at 65 kV. HVL values increase with thickness, indicating the need for thicker materials to achieve a 50% reduction in radiation intensity at higher attenuation levels. These findings highlight the novelty of quantitatively correlating thickness, attenuation effectiveness, and HVL within a single experimental framework and demonstrate that silicone rubber–PbO composite aprons have strong potential as a lightweight and flexible alternative to conventional lead aprons for clinical radiation protection at low-to-medium diagnostic X-ray energies.]]>
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