Disordered Microporous Sandia Octahedral Molecular Sieves are Tolerant to Neutron Radiation

Rana Faryad Ali, Melanie Gascoine, Krzysztof Starosta, Byron D. Gates
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Abstract

Materials that possess a porous and defected structure can have a range of useful properties that are sought after, which include their tolerance to nuclear radiation, ability to efficiently store and release isotopes, to immobilize nuclear waste, and to exhibit phase stability even at elevated temperatures. Since nanoscale pores and surface structures can serve as sinks for radiation-induced amorphization, one dimensional (1D) porous nanorods due to their high surface-to-volume ratio have the potential for use as advanced materials in nuclear science applications. In this study, we demonstrate a synthesis and a detailed analysis of microporous 1D octahedral molecular sieves of disodium diniobate hydrate (Na2Nb2O6 H2O) or Sandia Octahedral Molecular Sieves (SOMS). In addition, the stability of these SOMS is evaluated following their exposure to elevated temperatures and neutron irradiation. A surfactant-assisted solvothermal method is used to prepare these SOMS-based nanorods. This relatively low temperature, solution-phase approach can form crystalline nanorods of microporous Na2Nb2O6 H2O. These 1D structures had an average diameter of approximately 50 nm and lengths greater than 1 micrometer. The nanorods adopted a defected microporous phase, which also exhibited a resistance to radiation induced amorphization. The dimensions, phase, and crystallinity of the SOMS-based nanorods after exposure to a high incident flux of neutrons were comparable to those of the as-synthesized products. The radiation tolerance of these microporous SOMS could be useful in the design of materials for nuclear reactors, resilient nuclear fuels, thermally resilient materials, high temperature catalysts, and durable materials for the handling and storage of radioactive waste.
无序微孔桑迪亚八面体分子筛可耐受中子辐射
具有多孔和缺陷结构的材料可具有一系列受人追捧的有用特性,其中包括对核辐射的耐受性、有效储存和释放同位素的能力、固定核废料的能力以及即使在高温下也能表现出相稳定性的能力。由于纳米级孔隙和表面结构可作为辐射诱导变质的吸收池,一维(1D)多孔纳米棒因其高表面体积比,有可能用作核科学应用中的先进材料。在本研究中,我们展示了二铌酸钠水合物(Na2Nb2O6 H2O)或桑迪亚八面体分子筛(SOMS)的微孔一维八面体分子筛的合成和详细分析。此外,还对这些 SOMS 暴露于高温和中子辐照后的稳定性进行了评估。制备这些基于 SOMS 的纳米棒采用了表面活性剂辅助溶液热法。这种温度相对较低的溶液相方法可以形成微孔 Na2Nb2O6 H2O 结晶纳米棒。这些一维结构的平均直径约为 50 纳米,长度超过 1 微米。这些纳米棒采用了有缺陷的微孔相,也表现出了抗辐射诱导非晶化的能力。基于 SOMS 的纳米棒在暴露于高入射中子通量后的尺寸、相位和结晶度与合成产品相当。这些微孔 SOMS 的耐辐射性可用于设计核反应堆材料、弹性核燃料、热弹性材料、高温催化剂以及处理和储存放射性废物的耐用材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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