Fatigue Damage

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aluminum alloy; corrosive environment; fatigue performance; rotating bending test; relative strength; Alloy 617; very high temperature gas-cooled reactor (VHTR); gas tungsten arc welding (GTAW); weldments; low cycle fatigue (LCF); fatigue life; fracture surface characterization; creep-fatigue; creep-rupture; unified equation; fatigue model; Cu single crystal; coplanar double slip; pre-fatigue deformation; plastic strain amplitude; tensile behavior; compressive behavior; dislocation structure; estimation methods; monotonic properties; cyclic stress-strain parameters; Ramberg-Osgood; steel grouping; statistical analysis; PM steels; heterogeneous microstructure; retained austenite; fatigue crack growth; crack path tortuosity; severe plastic deformation; hardening; twins; fatigue; compressive residual stress; nanocrystallization; heavy-section ductile cast iron; chunky graphite; fatigue limit; fatigue crack growth resistance; fracture toughness; ultrasonic fatigue test; high-strength steel; plate specimen; butt welding; dynamic elastic modulus; corrosion fatigue; characteristic life prediction; 25CrMo steel; microscopic analysis; Weibull distribution; fatigue life; vibratory stress relief; titanium alloy Ti-6Al-4V; residual stress; annealing treatment; response surface methodology; machining parameters; design of experiments; thermal fatigue; 7075 aluminum alloy; solution treatment; high-cycle fatigue property; microstructure; creep fatigue; physical mechanism; temperature; cyclic time; grain size; fatigue capacity; n/a