Proton Irradiation Effects on Hardness and the Volta Potential of Welding 308L Duplex Stainless Steel

Proton Irradiation Effects on Hardness and the Volta Potential of Welding 308L Duplex Stainless Steel

308L welding duplex stainless steel has been irradiated at 360 °C with 2 MeV protons, corresponding to a dose of 3 dpa at the maximum depth of 20 μm. Microhardness of the δ-ferrite and austenite phases was studied before and after proton irradiation using in situ nanomechanical test system (ISNTS)....

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Bibliographic Details
Published in:Micromachines (Basel) Vol. 10; no. 1; p. 11
Main Authors: Jiang, Baolong, Peng, Qunjia, Jiao, Zhijie, Volinsky, Alex A, Qiao, Lijie
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 25-12-2018
MDPI
Subjects:
308L
Aging
Austenite
Corrosion potential
Damage
Defects
Delta ferrite
duplex microstructure
Duplex stainless steels
Experiments
High temperature
Hydrogen
micro-hardness
Microhardness
Microscopy
Monte Carlo simulation
Phases
Proton irradiation
Radiation
Reinforced reaction injection molding
Scanning probe microscopy
Stainless steel
Stress corrosion cracking
Topography
Volta potential
Welding
United States > US
Volta potential
micro-hardness
proton irradiation
duplex microstructure
308L
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Summary:308L welding duplex stainless steel has been irradiated at 360 °C with 2 MeV protons, corresponding to a dose of 3 dpa at the maximum depth of 20 μm. Microhardness of the δ-ferrite and austenite phases was studied before and after proton irradiation using in situ nanomechanical test system (ISNTS). The locations of the phases for indentations placement were obtained by scanning probe microscopy from the ISNTS. The hardness of the δ-ferrite had a close relationship with the vacancy distribution obtained from the Stopping and Range of Ions in Matter (SRIM) Monte Carlo simulation code. However, the hardness of the austenite phase in the maximum damage region (17⁻20 μm depth) from the SRIM simulation was decreasing sharply, and a hardness transition region (>20 μm and <55 μm depth) was found between the maximum damage region (17⁻20 μm depth) and the unirradiated region (>20 μm depth). However, the δ-ferrite hardness behavior was different. A hardness of the two phases increased on the irradiated surface and the interior due to different hardening mechanisms in the austenite and δ-ferrite phases after a long time high-temperature irradiation. A transition region (>20 μm and <55 μm depth) of the Volta potential was also found, which was caused by the deeper transfer of implanted protons measured by scanning Kelvin probe force microscopy.
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ISSN:2072-666X
2072-666X
DOI:10.3390/mi10010011