Preparing the future post-mortem analysis of beryllium-based JET and ITER samples by multi-wavelengths Raman spectroscopy on implanted Be, and co-deposited Be

Rusu, M. I.; Dinca, P.; Köppen, M.; Lungu, M.; Linsmeier, Ch.; Porosnicu, C.; Ferri, L.; Barrachin, M.; Hansen, P.; Giacometti, G.; Lungu, C. P.; Minissale, M.; Ferro, Y.; Martin, C.; Pardanaud, C.; Virot, F.; Addab, Y.; Roubin, P.

doi:10.1088/1741-4326/aa70bb

Journal Article

FZJ-2017-05133

Preparing the future post-mortem analysis of beryllium-based JET and ITER samples by multi-wavelengths Raman spectroscopy on implanted Be, and co-deposited Be

Rusu, M. I. ; Pardanaud, C. (Corresponding author) ; Ferro, Y. ; Giacometti, G. ; Martin, C. ; Addab, Y. ; Roubin, P. ; Minissale, M. ; Ferri, L. ; Virot, F. ; Barrachin, M. ; Lungu, C. P. ; Porosnicu, C. ; Dinca, P. ; Lungu, M. ; Köppen, M. ; Hansen, P.FZJ* ; Linsmeier, C.FZJ*

2017
IAEA Vienna

Nuclear fusion 57(7), 076035 (2017) [10.1088/1741-4326/aa70bb]

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Please use a persistent id in citations: doi:10.1088/1741-4326/aa70bb

Abstract: This study demonstrates that Raman microscopy is a suitable technique for future post mortem analyses of JET and ITER plasma facing components. We focus here on laboratory deposited and bombarded samples of beryllium and beryllium carbides and start to build a reference spectral databases for fusion relevant beryllium-based materials. We identified the beryllium phonon density of states, its second harmonic and E 2G and B 2G second harmonic and combination modes for defective beryllium in the spectral range 300–700 and 700–1300 cm−1, lying close to Be–D modes of beryllium hydrides. We also identified beryllium carbide signature, Be2C, combining Raman microscopy and DFT calculation. We have shown that, depending on the optical constants of the material probed, in depth sensitivity at the nanometer scale can be performed using different wavelengths. This way, we demonstrate that multi-wavelength Raman microscopy is sensitive to in-depth stress caused by ion implantation (down to ≈30 nm under the surface for Be) and Be/C concentration (down to 400 nm or more under the surface for Be+C), which is a main contribution of this work. The depth resolution reached can then be adapted for studying the supersaturated surface layer found on tokamak deposits.

Classification:

ddc:530

Contributing Institute(s):

Plasmaphysik (IEK-4)

Research Program(s):

113 - Methods and Concepts for Material Development (POF3-113) (POF3-113)

Appears in the scientific report 2017

Database coverage:
Current Contents - Physical, Chemical and Earth Sciences ; Ebsco Academic Search ; IF < 5 ; JCR ; National-Konsortium ; Nationallizenz

; SCOPUS ; Science Citation Index ; Science Citation Index Expanded ; Thomson Reuters Master Journal List ; Web of Science Core Collection

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Document types > Articles > Journal Article
Institute Collections > IFN > IFN-1
Workflow collections > Public records
IEK > IEK-4
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Record created 2017-07-25, last modified 2024-07-11

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