Structural, thermal, and radiation shielding properties of antimony-doped zinc borate glasses
Yurii Hordieiev, A. V. Zaichuk
Abstract
Antimony zinc borate glasses with compositions (45–m)ZnO–(55–n)B 2 O 3 –(m + n)Sb 2 O 3 (0 ≤ m, n ≤ 15 mol%) were synthesized via the melt-quenching technique to investigate the impact of Sb 2 O 3 substitution on structural, thermal, and radiation shielding properties. X-ray diffraction confirmed the amorphous nature of the synthesized glass samples. Fourier-transform infrared spectroscopy revealed significant structural rearrangements, including an increase in non-bridging oxygen content with rising Sb 2 O 3 concentrations, as evidenced by the shifting and intensification of characteristic absorption bands. Differential thermal analysis demonstrated that the glass transition temperature decreased from 580 °C to 490 °C with increasing Sb 2 O 3 , while the thermal stability parameter (ΔT) improved from 144 °C to 256 °C, particularly when B 2 O 3 was replaced. Density increased from 3.121 g/cm 3 to 3.836 g/cm 3 , and molar volume expanded from 24.01 cm 3 /mol to 31.16 cm 3 /mol. Radiation shielding performance was significantly enhanced: at 10 MeV, the linear attenuation coefficient increased from 0.0768 cm −1 to 0.1142 cm −1 (~ 49%) when replacing B 2 O 3 and to 0.0983 cm −1 (~ 28%) when replacing ZnO. The half-value layer decreased from 9.02 cm to 6.07 cm at 15 mol% Sb 2 O 3 , confirming improved photon attenuation. Overall, this work offers valuable insights into the interplay between composition, structure, and functional properties in Sb 2 O 3 -doped zinc borate glasses.