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The behaviour of 316L stainless steel in hydrogen
D. Eliezer
Department of Materials Engineering
Research output
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Contribution to journal
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Article
›
peer-review
18
Scopus citations
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Dive into the research topics of 'The behaviour of 316L stainless steel in hydrogen'. Together they form a unique fingerprint.
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Keyphrases
Grain Boundary
100%
Fracture Surface
100%
SS316L
100%
Cathodic Charging
100%
TEM Study
50%
Mechanical Properties
50%
Aging
50%
Annealing
50%
Phase Transition
50%
Room Temperature
50%
Micro-mechanism
50%
Microstructure
50%
High Stress
50%
Strain-induced
50%
Thin Plate
50%
Surface Crack
50%
Surface Stress
50%
Crystal Plane
50%
Grain Size
50%
Dislocation Structure
50%
High-density Dislocation
50%
Relative Role
50%
Tensile Test
50%
Hydrogen Embrittlement
50%
Stacking Faults
50%
Martensite
50%
Austenitic Stainless Steel
50%
Austenite
50%
Within-plate
50%
Tensile Specimen
50%
Intergranular Fracture
50%
Cathodic Polarization
50%
Microvoid Coalescence
50%
Fault Mechanism
50%
Microvoid nucleation
50%
Intergranular Cracking
50%
Material Science
Grain Boundary
100%
Stainless Steel
100%
Nucleation
50%
Surface Stress
50%
Grain Size
50%
Stacking Fault
50%
Dislocation Structure
50%
Hydrogen Embrittlement
50%
Martensite
50%
Austenitic Stainless Steels
50%
Austenite
50%
Intergranular Fracture
50%