Micron plate Sm2O3 composites enhance neutron and gamma radiation protection

Recently, Dr. HUO Zhipeng and his student LU Yidong from Hefei Institutes of Physical Science of Chinese Academy of Sciences created a new type of composite material for shielding against neutron and gamma radiation. They used micron plate Sm₂O₃, a type of rare earth-based filler, to reinforce boron-containing polyethylene.

The research results were published on Composites Science and Technology.

Radiation protection relies on time, distance, and shielding. High-energy neutrons and gamma rays can harm tissues and genes. Lead-based materials are commonly used for shielding, but they're toxic. Samarium, a rare earth element, is promising for shielding as it absorbs both neutrons and gamma rays. However, there's a need for more research on how the microstructure of materials affects their shielding properties. Developing rare earth fillers with specific characteristics could lead to better neutron-gamma shielding materials.

In this study, a series of micron plate Sm₂O₃ fillers with different specific surface areas and particle size distributions were synthesized by homogeneous coprecipitation method. They found that adjusting the synthesis process could produce fillers with uniform size and high surface area. These fillers were then added to boron-containing polyethylene to create composites. The composites showed improved thermal stability, mechanical strength, and radiation shielding properties compared to materials without the fillers.

Tests revealed that the composite material could block 98.7% of neutron radiation from a ²⁵²Cf source and 72.1% of gamma radiation from a ¹³⁷Cs source when the material was 15 cm thick.

This work provides a novel strategy for the development of radiation protection technology from the perspective of materials science.