Differences in the microstructure of the F82H ferritic/martensitic steel after proton and neutron irradiation

The microstructure of the F82H steel that is a candidate for the future fusion reactor first wall is investigated. Protons as well as fission neutrons are used to simulate the irradiation effects of the fusion environment. The differences in the He production rates between the two types of irradiation may lead to differences in the irradiation damage of the F82H microstructure. This paper presents a transmission electron microscopy (TEM) study for three different irradiation conditions: (i) in the PIREX facility with 590 MeV protons, (ii) with fission neutrons at the research reactor in Petten and (iii) with 590 MeV protons in PIREX followed by fission neutrons at the reactor in Studsvik. The latter experiment allows us to vary the He production rate for a given irradiation type. Total doses ranged from 0.3 to 10 dpa and temperatures ranged from room temperature to 310 degreesC. (C) 2000 Elsevier Science B.V. All rights reserved.

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2000
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https://infoscience.epfl.ch/record/119721?ln=fr

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Tensile properties and microstructure of 590 MeV proton-irradiated pure Fe and a Fe-Cr alloy

Polycrystalline pure Fe and Fe-12Cr alloy have been proton-irradiated to doses of 10(-3)-3 x 10(-1) dpa at room temperature and 523 K. Samples were mechanically tested in tension and transmission electron microscopy (TEM) was performed on the as-irradiated material as well as on the irradiated and deformed material. At room temperature, pure Fe presents an initial yield point, that increases with the dose, followed by a yield region, indicative of a localized deformation mode. The Fe-12Cr alloy shows the same behavior, but the irradiation amplifies the effects previously mentioned. No yield point or yield region appears after irradiation at 523 K. TEM observations of the irradiated material showed a high density of small defect clusters which increases with the dose. Defect-free channels are observed in Fe-12Cr irradiated and deformed at room temperature. Results of the present investigation are compared with neutron irradiation of similar materials. (C) 2000 Elsevier Science B.V. All rights reserved.

2000

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The mechanical properties and microstructure of the OPTIMAX series of low activation ferritic-martensitic steels

Nadine Baluc

Polycrystalline specimens of the ferritic-martensitic OPTIMAX A steel have been irradiated on the one hand with neutrons at 523 K to a dose of 2.5 dpa and with 590 MeV protons at ambient temperature and 523 K to doses of about 0.3 and 1 dpa on the other. Charpy tests reveal a shift of the ductile-to-brittle transition temperature from about 190 to 268 K in the neutron-irradiated steel. Proton irradiations at ambient temperature lead to hardening and reduction of tensile ductility of the material. Both phenomena are strongly and positively dependent on dose. After irradiation at 523 K, they appear negligible (at least for the dose of 0.75 dpa). Transmission electron microscopy observations reveal that neutron irradiation leads to the formation of only a few Visible black dots, together with a few faceted cavities, while proton irradiations also produce few visible defect clusters with sizes of about 1-2 nm, with no clear difference in size and density with dose and temperature. As a particular result, from proton irradiations performed at ambient temperature, the embedded carbides become amorphous, while at 523 K they remain crystalline. (C) 2000 Elsevier Science B.V. All rights reserved.

2000

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The impact of irradiation temperature on the microstructure of F82H martensitic/ferritic steel irradiated in a proton and neutron mixed spectrum

Yong Dai

F82H low-activation martensitic steel was irradiated in the Swiss Spallation Neutron Source (SINQ) Target-III to irradiation doses of 10-12 dpa in a temperature range of 140-360 degreesC. Transmission electron microscope observations have been performed to study the radiation effects on the microstructure at different irradiation temperatures. The results show: (1) High-density helium bubbles of size greater than or equal to 1 nm are observed in the samples irradiated at temperatures greater than or equal to 175 degreesC. The size of bubbles increases with increasing irradiation temperature, but the density remains almost constant. (2) The irradiation temperature is the controlling parameter for the amorphization of the precipitates in F82H steel. Present work indicates that the amorphous temperature for typical precipitates (M23C6) is about 235 degreesC corresponding to about 0.3T(m) (T-m is the absolute melting point temperature) of the steel. (3) With increasing irradiation temperature, the mean size of the defect clusters remains almost constant below 235 degreesC but increases rapidly at higher temperatures. The density of defect clusters shows no significant change up to 255 degreesC and then decreases rapidly above this temperature. (C) 2002 Elsevier Science B.V. All rights reserved.

2002

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Irradiation

L'irradiation désigne l'exposition, volontaire ou accidentelle, d'un organisme, d'une substance, d'un corps, à des rayonnements. Ce terme est en particulier utilisé lorsque l'on considère l'expositio

Irradiation des aliments

thumb|Unité mobile d'irradiation alimentaire dans les années 1960 L'irradiation des aliments consiste à exposer des aliments à des rayonnements ionisants afin de réduire le nombre de micro-organismes

Microscopie électronique en transmission

vignette|upright=1.5|Principe de fonctionnement du microscope électronique en transmission. vignette|Un microscope électronique en transmission (1976). La microscopie électronique en transmission (ME