Litcius/Paper detail

Transition mechanism of cycle- to time-dependent acceleration of fatigue crack-growth in 0.4 %C Cr-Mo steel in a pressurized gaseous hydrogen environment

Atsuki Setoyama, Yuhei Ogawa, Masami Nakamura, Yuya Tanaka, Tingshu Chen, Motomichi Koyama, Hisao Matsunaga

2022International Journal of Fatigue35 citationsDOIOpen Access PDF

Abstract

Fatigue crack-growth (FCG) tests were conducted in 90-MPa-hydrogen gas on three martensitic steels with tensile strengths of 811, 921 and 1025 MPa. Increased strength levels resulted in augmented, hydrogen-induced FCG acceleration. In the highest-strength material, the FCG rate per cycle was dependent on test frequency, i.e., the crack-growth distance was proportional to load duration. Several observations and analyses revealed that such time-dependent FCG was due to stress-driven cracking along hierarchical martensite boundaries, stemming from the hydrogen-induced degradation of their cohesive strengths as a result of competition between mechanically-determined crack-tip stress (driving stress) and statistically-distributed boundary strength (resistance stress).

Topics & Concepts

Materials scienceParis' lawCrackingHydrogenMartensiteMetallurgyUltimate tensile strengthComposite materialStress (linguistics)AccelerationStructural engineeringCrack closureFracture mechanicsMicrostructureEngineeringChemistryLinguisticsPhysicsPhilosophyOrganic chemistryClassical mechanicsHydrogen embrittlement and corrosion behaviors in metalsFatigue and fracture mechanicsMaterial Properties and Failure Mechanisms