Recent Advances in Mechanisms of Fracture and Fatigue

© 2022 by the authors; CC BY-NC-ND license

cyclic indentation; Vickers hardness; inverse analysis; numerical simulations; cyclic material properties; fatigue life; advanced high-strength steels; hydrogen embrittlement; in-situ testing; scanning electron microscopy; plasma charging; coarse-grained Ni-based superalloys; crystal plasticity; notch effect; strain concentration factor; hull fracture; inspection manholes; bulk carrier; cracks; corrosion fatigue; steel quality; cleavage fracture; finite element analysis; local approach; Weibull stress; synchrotron tomography; short fatigue crack growth; residual stress; crystal plasticity; very high cycle fatigue; silicon carbide; ceramic matrix composites; creep properties; high-temperature strength; molecular dynamics; artificial neural network; forged titanium alloy; low-cycle fatigue; cycle wave form; durability; crack meso-tunneling; fractography; crack growth duration; ultrasonic fatigue; frequency effect; strain rate effect; environmental effect; size effect; high cycle fatigue; very high cycle fatigue; underload cycles; crack closure; threshold; fatigue crack growth; oxidation; EA4T steel; fracture; gigacycle fatigue; surface morphology; kinetic equation; laminated metallic composites; toughening mechanisms; interfaces; fatigue crack propagation; fatigue crack growth; large chamber SEM; ultra-high steel grades; tensile characteristics; fracture toughness; temperature dependence; modelling fracture; fracture toughness; ductile-to-brittle transition; local approach to fracture; ferritic steel; synchrotron radiation X-ray imaging; fatigue performance; fatigue crack; FGH96 alloy; microstructure; micro-indentation; mechanical and fracture properties identification; finite element analysis; optimisation analysis; 316L stainless steel; selective laser melting; microstructure; fatigue damage