Deuterium diffusion in proton-irradiated oxide layer of zirconium alloy has been in situ examined at 573 K by using a combined technique of deuterium plasma exposure and nuclear reaction analysis of the D(~3He,p) ~4He reaction. The zirconium alloy used was GNF-Ziron (a high iron Zircaloy-2 type alloy), which had been corroded in high temperature steam, producing an oxide layer of 1.6-1.7 μm thickness. Oxidized specimens were irradiated at ambient temperature with 350 keV H + ions, and the total fluence was 1 × 10 ~(17) cm ~(-2). An outer non-protective oxide layer of 0.5-0.6 μm thickness, which was observed in the unirradiated oxide layer, evolved into the protective barrier oxide due to the proton irradiation. The evaluated diffusion coefficients in the barrier layer were almost identical for both the unirradiated and irradiated oxides. From X-ray diffraction measurements, lattice expansion and high compressive stress were found in the proton-irradiated oxide. The most probable mechanism for evolution of the diffusion property in the irradiated oxide was ascribed to the increase of the compressive stress induced by the constraint of the damage-accumulated oxide layer by the thick metal substrate.
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机译:通过使用氘等离子体暴露和D(〜3He,p)〜4He反应的核反应分析的组合技术,在573 K下对锆合金质子辐照氧化物层中的氘扩散进行了原位检查。所使用的锆合金是GNF-Ziron(高铁Zircaloy-2型合金),该合金已在高温蒸汽中腐蚀,产生了1.6-1.7μm的氧化层。在室温下用350 keV H +离子辐照氧化的样品,总通量为1×10〜(17)cm〜(-2)。在未照射的氧化物层中观察到的厚度为0.5-0.6μm的外部非保护性氧化物层由于质子照射而演变成保护性阻挡氧化物。对于未辐照的氧化物和辐照的氧化物,在阻挡层中评估的扩散系数几乎相同。通过X射线衍射测量,在质子辐照的氧化物中发现了晶格膨胀和高压缩应力。在被辐照的氧化物中扩散特性发展的最可能的机理归因于由厚金属基底限制了累积损伤的氧化物层而引起的压应力的增加。
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