322 research outputs found
Role of proton irradiation and relative air humidity on iron corrosion
This paper presents a study of the effects of proton irradiation on iron
corrosion. Since it is known that in humid atmospheres, iron corrosion is
enhanced by the double influence of air and humidity, we studied the iron
corrosion under irradiation with a 45% relative humidity. Three proton beam
intensities (5, 10 and 20 nA) were used. To characterise the corrosion layer,
we used ion beam methods (Rutherford Backscattering Spectrometry (RBS), Elastic
Recoil Detection Analysis (ERDA)) and X-ray Diffraction (XRD) analysis. The
corrosion kinetics are plotted for each proton flux. A diffusion model of the
oxidant species is proposed, taking into account the fact that the flux through
the surface is dependent on the kinetic factor K. This model provides evidence
for the dependence of the diffusion coefficient, D, and the kinetic factor, K,
on the proton beam intensity. Comparison of the values for D with the diffusion
coefficients for thermal oxygen diffusion in iron at 300 K suggests an
enhancement due to irradiation of 6 orders of magnitude
Fission Enhanced diffusion of uranium in zirconia
This paper deals with the comparison between thermal and Fission Enhanced
Diffusion (FED) of uranium into zirconia, representative of the inner face of
cladding tubes. The experiments under irradiation are performed at the Institut
Laue Langevin (ILL) in Grenoble using the Lohengrin spectrometer. A thin
layer in direct contact with an oxidized zirconium foil is
irradiated in the ILL high flux reactor. The fission product flux is about
10 ions cm s and the target temperature is measured by an
IR pyrometer. A model is proposed to deduce an apparent uranium diffusion
coefficient in zirconia from the energy distribution broadening of two selected
fission products. It is found to be equal to 10 cm s at
480C and compared to uranium thermal diffusion data in ZrO in the
same pressure and temperature conditions. The FED results are analysed in
comparison with literature data
Comparative study of radiation-induced damage in magnesium aluminate spinel by means of IL, CL and RBS/C techniques
International audienceA comparative study of damage accumulation in magnesium aluminate spinel (MgAl2O4) has been conducted using ionoluminescence (IL), cathodoluminescence (CL) and Rutherford Backscattering Spectrometry/channeling (RBS/C) techniques. MgAl2O4 single crystal and polycrystalline samples were irradiated with 320 keV Ar+ ions at fluencies ranging from 1 Ă 1012 to 2 Ă 1016 cmâ2 in order to create various levels of radiation damage. RBS/C measurements provided quantitative data about damage concentration in the samples. These values were then compared to the luminescence measurements. The results obtained by IL and RBS/C methods demonstrate a two-step character of damage buildup process. The CL data analysis points to the three-step damage accumulation mechanism involving the first defect transformation at fluencies of about 1013 cmâ2 and second at about 1015 cmâ2. The rate of changes resulting from the formation of nonluminescent recombination centers is clearly nonlinear and cannot be described in terms of continuous accumulation of point defects. Both, IL and CL techniques, appear as new, complementary tools bringing new possibilities in the damage accumulation studies in single- and polycrystalline materials
Use of the point defect model to interpret the iron oxidation kinetics under proton irradiation
This article concerns the study of iron corrosion in wet air under mega-electron-volt proton irradiation for different fluxes at room temperature and with a relative humidity fixed to 45%. Oxidized iron sample surfaces are characterized by ion beam analysis (Rutherford backscattering spectrometry and elastic recoil detection analysis), for the elemental analysis. The structural and physicochemical characterization is performed using the x-ray photoelectron spectroscopy and transmission electron microscopy techniques. We have also measured the iron oxidation kinetics. Radiation enhanced diffusion and transport processes have been evidenced. The modeling of the experimental data shows that the apparent oxygen diffusion coefficient increases whereas the oxygen transport velocity decreases as function of flux. Finally, the point defect model has been used to determine the electric field value in the samples. Results have shown that the transport process can be attributed to the presence of an electrical potential gradient
Zirconium oxidation under high energy heavy ion irradiation
This paper concerns the study of zirconium oxidation under irradiation with
high energetic Xe ions. The irradiations were performed on the IRRSUD beam line
at GANIL (Caen). The oxygen partial pressure was fixed at 10 Pa and two
temperature conditions were used, either 480C reached by Joule effect
heating or 280C due to Xe energy deposition. Zirconia was fully
characterized by Rutherford Backscattering Spectrometry, Transmission Electron
Microscopy and Grazing Angle X-ray Diffraction. Apparent diffusion coefficients
of oxygen in ZrO2 were determined from these experiments by using a model which
takes into account a surface exchange between oxygen gas and the ZrO2 surface.
These results are compared with thermal oxidation data
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