Characterisation of radiation damage in W and W-based alloys from 2 MeV self-ion near-bulk implantations

Yi, Xiaoou; Jenkins, M. L.; Hattar, Khalid Mikhiel; Edmondson, Philip D.; Roberts, Steve

doi:10.1016/j.actamat.2015.04.015

Cited by 162 publications

(107 citation statements)

References 57 publications

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“…Therefore, the defects in thin and thick samples can be expected to be different. However, for fast heavy ion irradiation, no difference was observed in a recent study in W [48], likely because the defect size is generally small in heavy ion irradiation. Our irradiation was carried out using rapid heavy ion irradiation conditions (around 10 min for 1 dpa).…”

Section: Effect Of Structure On the Precipitate Stabilitymentioning

confidence: 79%

Precipitate Stability in a Zr–2.5Nb–0.5Cu Alloy under Heavy Ion Irradiation

Dong

Yao

Wang

et al. 2017

Metals

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Abstract:The stability of precipitates in Zr-2.5Nb-0.5Cu alloy under heavy ion irradiation from 100 • C to 500 • C was investigated by quantitative Chemi-STEM EDS analysis. Irradiation results in the crystalline to amorphous transformation of Zr 2 Cu between 200 • C and 300 • C, but the β-Nb remains crystalline at all temperatures. The precipitates are found to be more stable in starting structures with multiple boundaries than in coarse grain structures. There is an apparent increase of the precipitate size and a redistribution of the alloying element in certain starting microstructures, while a similar size change or alloying element redistribution is not detected or only detected at a much higher temperature in other starting microstructures after irradiation.

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Section: Effect Of Structure On the Precipitate Stabilitymentioning

confidence: 79%

Precipitate Stability in a Zr–2.5Nb–0.5Cu Alloy under Heavy Ion Irradiation

Dong

Yao

Wang

et al. 2017

Metals

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“…Ciupi nski et al [26] and Yi et al [27] have used self-ion irradiation to study trends with dose (0.01e30 dpa) and irradiation temperature (300e1023 K) for <001>-grains 1 [28] of W and W-alloys, utilising cross-sectional and planar specimen geometries respectively. Both sets of authors confirmed that in Stage II, loops with b ¼ ½ <111> (~75%) and b ¼ <100> coexist, and were mostly 6 nm in diameter and interstitial in nature [22].…”

Section: Introductionmentioning

confidence: 99%

In-situ TEM studies of 150 keV W+ ion irradiated W and W-alloys: Damage production and microstructural evolution

et al. 2016

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a b s t r a c tIn-situ irradiations with 150 keV W þ ions have been performed on W and W-5wt.% (Re; Ta; V) alloys in a comprehensive study of the influences of irradiation temperature T irr , dose, alloying elements and grain orientations on radiation damage production and microstructural evolution. For T irr between 30 K and 1073 K, the first observable defects in pure W appeared at doses 0.01 dpa, and were most likely vacancy loops, with Burgers vectors predominantly of type b ¼ ½ <111>. With increasing T irr , the retained defect concentration decreased strongly and the maximum cluster size increased from~1300 point defects at 30 K to~2300 point defects at 1073 K. At all irradiation temperatures, the evolution of damage microstructures with dose from 0.1 to 1.0 dpa involved defect cluster migration, with mutual elastic interactions often leading to spatial inhomogeneities and loop reactions. In pure W, spatial ordering of loops was observed at doses >0.4 dpa and T irr ! 773 K in grains close to z ¼ <001>. No such ordering was found in similar grain orientations for the W-(Re; Ta) alloys, but it was found in the non-z ¼ <001> grains. Post-irradiation analysis on W and W-5 wt% (Re; Ta) at 1.0 dpa showed that ½ <111> and <100> loops of both vacancy and interstitial type were present, at number densities~10 15 loops m À2 . In all cases ½ <111> loops were dominant, the fraction of these with interstitial nature increased with T irr , and the proportion of <100> loops decreased with increasing T irr . Compared with pure W, microstructures in the W-(Re; Ta) alloys exhibited higher loop number densities and evolved more quickly with increasing dose towards damage saturation.

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“…Interstitial-type dislocation loops form at those low irradiation temperatures in W-Ta alloys. The loop size is smaller and the loop number density is higher than in tungsten under equivalent irradiation conditions [19]. The low-temperature irradiation-hardening due to dislocation loops saturates at a damage level of 13 dpa at 300°C [20].…”

Section: Introductionmentioning

confidence: 90%

“…The low-temperature irradiation-hardening due to dislocation loops saturates at a damage level of 13 dpa at 300°C [20]. Ta is predicted to have a repulsive interaction with self-interstitial atom (SIA) defects such as \111[ crowdion [21] and dumbbell [22] configurations, and potentially restrict the mobility of SIAs and interstitial loops in W [19].…”

Section: Introductionmentioning

confidence: 99%

Thermal Evolution of the Proton Irradiated Structure in Tungsten–5 wt% Tantalum

et al. 2017

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We have monitored the thermal evolution of the proton irradiated structure of W-5 wt% Ta alloy by in-situ annealing in a transmission electron microscope at fusion reactor temperatures of 500-1300°C. The interstitial-type a/2\111[ dislocation loops emit self-interstitial atoms and glide to the free sample surface during the early stages of annealing. The resultant vacancy excess in the matrix originates vacancy-type a/2\111[ dislocation loops that grow by loop and vacancy absorption in the temperature range of 600-900°C. Voids form at 1000°C, by either vacancy absorption or loop collapse, and grow progressively up to 1300°C. Tantalum delays void formation by a vacancy-solute trapping mechanism.

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Characterisation of radiation damage in W and W-based alloys from 2 MeV self-ion near-bulk implantations

Cited by 162 publications

References 57 publications

Precipitate Stability in a Zr–2.5Nb–0.5Cu Alloy under Heavy Ion Irradiation

Precipitate Stability in a Zr–2.5Nb–0.5Cu Alloy under Heavy Ion Irradiation

In-situ TEM studies of 150 keV W+ ion irradiated W and W-alloys: Damage production and microstructural evolution

Thermal Evolution of the Proton Irradiated Structure in Tungsten–5 wt% Tantalum

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