Hong Zhang , Xuexi Zhang , Yuhong Li , Peng Wang , Li Qiao
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引用次数: 0
Abstract
Irradiation hardening is one of the service performance concerns for tungsten in fusion reactors. This work investigated the effect of deuterium (D) plasma exposure and helium (He) ions irradiation on the hardening behavior of the same tungsten sample using nanoindentation. The results demonstrate that the hardness of tungsten increases after D plasma exposure, He ions irradiation, and synergistic irradiation of He-ion and D-plasma. In general, the degree of hardening is He-ion + D-plasma irradiation, individual He-ion irradiation, and D plasma exposure in descending order. D plasma exposure results in an increase in hardness of more than 10 %, which is attributed to the pinning of dislocations by D plasma-induced defects and D-defect complexes (clusters). In the case of the He-ion irradiated tungsten, a large number of defects such as He nanobubbles induced by He-irradiation result in a 70 % increase in hardness. The superposition effect on the hardening of tungsten by D plasma exposure after He ions irradiation was observed, which essentially remains an increase in hardness due to D plasma exposure. This implies that the degradation of mechanical properties caused by D plasma exposure on tungsten will not be overlapped by other particle irradiation. Moreover, He bubbles in tungsten remain stable and grow slightly after annealing at 1173 K, resulting in a limited decrease in hardness.
辐照硬化是聚变反应堆中钨的服役性能问题之一。本研究利用纳米压痕法研究了氘(D)等离子体暴露和氦(He)离子辐照对同一钨样品硬化行为的影响。结果表明,经过氘等离子体暴露、氦离子照射以及氦离子和氘等离子体协同照射后,钨的硬度会增加。一般来说,硬化程度从高到低依次为 He 离子+D 等离子辐照、单独 He 离子辐照和 D 等离子辐照。D 等离子辐照可使硬度提高 10%以上,这归因于 D 等离子引发的缺陷和 D 缺陷复合物(簇)对位错的钉扎作用。在氦离子辐照钨的情况下,氦离子辐照诱发的大量缺陷(如氦纳米气泡)导致硬度增加了 70%。在氦离子照射后,观察到 D 等离子体照射对钨硬化的叠加效应,基本上仍是 D 等离子体照射导致硬度增加。这意味着 D 等离子辐照对钨造成的机械性能退化不会与其他粒子辐照重叠。此外,在 1173 K 退火后,钨中的 He 气泡保持稳定并略有增长,从而导致硬度的有限降低。
期刊介绍:
The open-access journal Nuclear Materials and Energy is devoted to the growing field of research for material application in the production of nuclear energy. Nuclear Materials and Energy publishes original research articles of up to 6 pages in length.