Evolution of small defect clusters in ion-irradiated 3C-SiC: Combined cluster dynamics modeling and experimental study

Liu, Cheng; He, Lenian; Zhai, Y.; Tyburska-Püschel, B.; Voyles, Paul M.; Sridharan, Kumar; Morgan, Dane; Szlufarska, Izabela

doi:10.1016/j.actamat.2016.12.020

Cited by 62 publications

(39 citation statements)

References 63 publications

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“…Note that the average number of visible defects per cascade is order 0.1-0.3, indicating that most cascades do not produce any visible defects. We observe that smallerand therefore also fainter-spots are more difficult to confidently identify on the micrograph, a conclusion also reached recently by Liu et al [17]. Figure 2 makes it plain that the 'count' and 'average' diameter of defects are both functions of the intensity threshold used.…”

supporting

confidence: 81%

Experimental observation of the number of visible defects produced in individual primary damage cascades in irradiated tungsten

Mason¹,

Yi²,

Sand³

et al. 2018

EPL

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We present a new analysis of nanoscale lattice defects observed after low-dose in situ self-ion irradiation of tungsten foils at cryogenic temperature. For decades, defect counts and size-frequency histograms have been the standard form of presenting a quantitative analysis of the nanoscale "black-dot" damage typical of such irradiations. Here we demonstrate a new statistical technique for generating a probability distribution for the number of defects produced in a single cascade. We show that while an average of fewer than one defect is observed per incident ion, the number of cascades with two or more visible defects produced is significant.

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supporting

confidence: 81%

Experimental observation of the number of visible defects produced in individual primary damage cascades in irradiated tungsten

Mason¹,

Yi²,

Sand³

et al. 2018

EPL

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“…Figure 2 shows a sequence of BF-TEM images of SiC irradiated to 5.0 DPA at an irradiation temperature of 400°C. It can be seen from the images that, as the irradiation dose increases, there is an increase in so-called "black spot" damage accumulation which has been observed in SiC under irradiation previously and is attributed to interstitial clusters [31], [32]. These black spots, however, do not appear to grow in size and remain ~5 nm in diameter up to 5.0 DPA.…”

Section: Amorphisation At Room Temperaturementioning

confidence: 75%

Damage microstructure evolution of helium ion irradiated SiC under fusion relevant temperatures

Harrison

Ebert

Hinks

et al. 2018

Journal of the European Ceramic Society

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In-situ transmission electron microscopy (TEM) with ion irradiation has been used to study the damage microstructure evolution of He ion irradiated 4-H SiC at nuclear fusion relevant temperatures. The SiC samples were irradiated with 20 keV He ions at 25, 400, 800 and 1200°C to a dose of 5.0 displacements per atom (DPA). At 25°C, the material fully amorphises at 1.5 DPA and no He bubble nucleation occurs up to the doses studied. At 400 and 800°C, He bubble nucleation occurs and the material remains crystalline. Bubble nucleation occurs at 2.0 DPA at 400°C but occurs at only 0.5 DPA at 1200°C. This is attributed the He atoms de-trapping from vacancies and migrating interstitially to larger He-vacancy clusters at higher temperatures, leading to faster nucleation of observable He bubbles. Helium platelets form at an irradiation temperature of 1200°C at 0.5 DPA showing a preference for nucleation between the {0001} basal planes.

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“…There is a minimum observable defect size in a TEM experiment, where the intensity of the defect becomes undetectable from background noise and, concurrently, the resolution limit of the microscope is reached. It is generally considered that, under our imaging conditions, defects of diameter < 1.5nm can not be seen, and for diameter < 2nm the count is likely to be low [9,38] For this work we assume that we see only defects with diameter > 2nm, ( n ≥ 55 ), whereas in the MD simulations we were taking into account defect clusters containing more than n ≥ 13. The apparent reduced size of defects in MD is actually just an artefact of the small number of simulations performed [6,9].…”

Section: Resultsmentioning

confidence: 99%

Direct observation of the spatial distribution of primary cascade damage in tungsten

Mason

Sand

et al. 2018

Acta Materialia

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Recently we have presented direct experimental evidence for large defect clusters being formed in primary damage cascades in self-ion irradiated tungsten [Yi et al, EPL 110:36001 (2015)]. This large size is significant, as it implies strong elastic interaction between the defects will affect their subsequent evolution, especially if defects are formed close together. Here we present a direct experimental observation of the separation between visible defects in self-ion irradiated tungsten, in the form of a 2d pairwise radial distribution function extracted from transmission electron micrographs (TEM). We also present a detailed analysis of the observed radial distribution function, and infer the probable size and shape of individual cascades. We propose and validate a simple exponential form for the spatial distribution of defects within a single cascade. The cascade statistics necessary have been acquired by developing an automated procedure for analyzing black-dot damage in TEM micrographs. We confirm that the same model also produces a high-quality fit to the separation between larger defects observed in MD simulations. For the first time we present experimental evidence for the sub-nanometre-scale spatial distribution of defect clusters within individual cascades.

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Evolution of small defect clusters in ion-irradiated 3C-SiC: Combined cluster dynamics modeling and experimental study

Cited by 62 publications

References 63 publications

Experimental observation of the number of visible defects produced in individual primary damage cascades in irradiated tungsten

Experimental observation of the number of visible defects produced in individual primary damage cascades in irradiated tungsten

Damage microstructure evolution of helium ion irradiated SiC under fusion relevant temperatures

Direct observation of the spatial distribution of primary cascade damage in tungsten

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