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High Cr ODS steels performance under supercritical water environment
Radek Novotný
*
, Přemysl Janík
, Sami Penttilä
, Peter Hähner
, Jan Macák
, Jan Siegl
, Peter Haušild
*
Corresponding author for this work
Joint Research Centre (JRC), Petten
University of Chemistry and Technology, Prague
Czech Technical University (CTU)
Research output
:
Contribution to journal
›
Article
›
Scientific
›
peer-review
38
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Keyphrases
Water Environment
100%
Supercritical Water
100%
Cr Oxide
100%
Higher CR
100%
Oxide Dispersion Strengthening
100%
Corrosion Resistance
66%
High Temperature
33%
Microstructure
33%
Cold Working
33%
Corrosion Rate
33%
Coupons
33%
Long-term Exposure
33%
Oxidation Rate
33%
Surface Treatment
33%
High Pressure
33%
Weight Gain
33%
Fuel Cladding
33%
Energy Dispersive X-ray Spectroscopy
33%
Oxide Layer
33%
Reactor Conditions
33%
Scanning Electron Microscope
33%
Light Water Reactor
33%
General Corrosion
33%
PM2000
33%
MA956
33%
Ferritic
33%
Surface Finish
33%
Weight Change
33%
Scanning Electron Microscopic Study
33%
Peak Cladding Temperature
33%
Corrosion Study
33%
Austenitic Alloys
33%
Nodular Corrosion
33%
Thermodynamic Critical Point
33%
Supercritical Water Corrosion
33%
Surface Orientation
33%
Thin-walled Component
33%
X-ray Diffraction (XRD) Analysis
33%
INIS
performance
100%
environment
100%
water
100%
oxides
100%
dispersions
100%
steels
100%
surfaces
60%
corrosion
60%
scanning electron microscopy
40%
corrosion resistance
40%
weight
40%
cladding
40%
layers
20%
design
20%
energy
20%
fuels
20%
steady-state conditions
20%
microstructure
20%
high temperature
20%
oxidation
20%
alloys
20%
peaks
20%
gain
20%
reactors
20%
walls
20%
spectroscopy
20%
investigations
20%
cross sections
20%
thermodynamics
20%
x-ray diffraction
20%
orientation
20%
austenitic steels
20%
ferritic steels
20%
nodular corrosion
20%
Engineering
Corrosion Resistance
100%
Scanning Electron Microscope
100%
Corrosion Rate
50%
General Corrosion
50%
X-Ray Diffraction Analysis
50%
Oxide Layer
50%
Light Water Reactors
50%
Oxidation Rate
50%
Cold Work
50%
Exposure Time
50%
Good Resistance
50%
Corrosion Study
50%
Sample Surface
50%
Surface Effect
50%
Cross Section
50%
Upper Limit
50%
Critical Point
50%
Material Science
Corrosion
100%
Oxide Compound
100%
Surface (Surface Science)
75%
Corrosion Resistance
50%
Scanning Electron Microscopy
50%
X Ray Diffraction Analysis
25%
Conceptual Design
25%