Different Radiation Tolerances of Ultrafine-Grained Zirconia–Magnesia Composite Ceramics with Different Grain Sizes

Abstract: Developing high-radiation-tolerant inert matrix fuel (IMF) with a long lifetime is important for advanced fission nuclear systems. In this work, we combined zirconia (ZrO2) with magnesia (MgO) to form ultrafine-grained ZrO2–MgO composite ceramics. On the one hand, the formation of phase interfaces can stabilize the structure of ZrO2 as well as inhibiting excessive coarsening of grains. On the other hand, the grain refinement of the composite ceramics can increase the defect sinks. Two kinds of composite cerami… Show more

“…The ultrafine-grained zirconiamagnesia (ZrO 2 -MgO composite) ceramics were obtained by spark plasma sintering (SPS). [103] The phase interfaces can stabilize the structure of ZrO 2 , as well as inhibits excessive radiation-induced coarsening and increases the defect sinks. The dual-phase composite ceramics had better radiation tolerance than the pure YSZ and MgO.…”

Recent Progress on Interfaces in Nanomaterials for Nuclear Radiation Resistance

“…The ultrafine-grained zirconiamagnesia (ZrO 2 -MgO composite) ceramics were obtained by spark plasma sintering (SPS). [103] The phase interfaces can stabilize the structure of ZrO 2 , as well as inhibits excessive radiation-induced coarsening and increases the defect sinks. The dual-phase composite ceramics had better radiation tolerance than the pure YSZ and MgO.…”

Recent Progress on Interfaces in Nanomaterials for Nuclear Radiation Resistance

He2+ irradiation response of structural evolution at different depths of MgO-Nd2(Zr1-Ce )2O7 composite ceramics used for inert matrix fuel

Constructing high-performance radiation-resistant ternary YSZ-MgO-CNT nanocomposites via tailored nanostructures