The high cycle fatigue behavior, failure characteristics, and fatigue life empirical relationship of 9% Cr steel under different stress ratios at 630 ℃

[1]  F. Xuan,et al.  Creep-fatigue interaction and damage behavior in 9-12%Cr steel under stress-controlled cycling at elevated temperature: Effects of holding time and loading rate , 2022, International Journal of Fatigue.

[2]  D. Ponge,et al.  The dual role of martensitic transformation in fatigue crack growth , 2022, Proceedings of the National Academy of Sciences of the United States of America.

[3]  N. Gao,et al.  Multiaxial fatigue behaviour and damage mechanisms of P92 steel under various strain amplitudes and strain ratios at high temperature , 2022, International Journal of Fatigue.

[4]  T. Kirste,et al.  The fatigue life of 42CrMo4 steel in the range of HCF to VHCF at elevated temperatures up to 773 K , 2021 .

[5]  N. Narasaiah,et al.  A re-visit to the Haigh diagram with the effect of creep damage on the high cycle fatigue behavior of alloy 617M , 2021 .

[6]  Yongjie Liu,et al.  Cyclic responses and microstructure sensitivity of Cr-based turbine steel under different strain ratios in low cycle fatigue regime , 2021 .

[7]  Yongjie Liu,et al.  Low cycle fatigue properties, damage mechanism, life prediction and microstructure of MarBN steel: Influence of temperature , 2021 .

[8]  W. Yao,et al.  The effect of porosity size on the high cycle fatigue life of nickel-based single crystal superalloy at 980 °C , 2021 .

[9]  R. Misra,et al.  Relationship between non-inclusion induced crack initiation and microstructure on fatigue behavior of bainite/martensite steel in high cycle fatigue/very high cycle (HCF/VHCF) regime , 2021 .

[10]  Qingyuan Wang,et al.  A comparative study of low cycle fatigue behavior and microstructure of Cr-based steel at room and high temperatures , 2020 .

[11]  T. Lampke,et al.  Equal-channel angular pressing influencing the mean stress sensitivity in the high cycle fatigue regime of the 6082 aluminum alloy , 2020 .

[12]  I. Singh,et al.  Effect of double austenitization treatment on fatigue crack growth and high cycle fatigue behavior of modified 9Cr–1Mo steel , 2020, Materials Science and Engineering: A.

[13]  J. Xiong,et al.  Effect of stress ratio on HCF and VHCF properties at temperatures of 20 °C and 700 °C for nickel-based wrought superalloy GH3617M , 2019, Chinese Journal of Aeronautics.

[14]  Youshi Hong,et al.  High‐cycle and very‐high‐cycle fatigue behaviour of a titanium alloy with equiaxed microstructure under different mean stresses , 2019, Fatigue & Fracture of Engineering Materials & Structures.

[15]  U. Krupp,et al.  Investigations of fatigue damage in tempered martensitic steel in the HCF regime , 2019, International Journal of Fatigue.

[16]  G. Gao,et al.  Effect of inclusion and microstructure on the very high cycle fatigue behaviors of high strength bainite/martensite multiphase steels , 2019, Materials Science and Engineering: A.

[17]  F. Dunne,et al.  A microstructure-sensitive driving force for crack growth , 2018, Journal of the Mechanics and Physics of Solids.

[18]  F. Lu,et al.  Characterization of high-gradient welded microstructure and its failure mode in fatigue test , 2018 .

[19]  Ming-Liang Zhu,et al.  Failure mechanisms and design of dissimilar welds of 9%Cr and CrMoV steels up to very high cycle fatigue regime , 2018, International Journal of Fatigue.

[20]  E. Kerscher,et al.  The role of local plasticity during very high cycle fatigue crack initiation in high-strength steels , 2018, International Journal of Fatigue.

[21]  Li Zhuguo,et al.  Microstructure characterization and HCF fracture mode transition for modified 9Cr-1Mo dissimilarly welded joint at different elevated temperatures , 2017 .

[22]  Sangshik Kim,et al.  Tensile and high cycle fatigue behaviors of high-Mn steels at 298 and 110 K , 2017 .

[23]  C. Tasan,et al.  Multiple mechanisms of lath martensite plasticity , 2016 .

[24]  David L. McDowell,et al.  Failure of metals II: Fatigue , 2016 .

[25]  S. Stanzl-Tschegg,et al.  Pit-to-crack transition under cyclic loading in 12% Cr steam turbine blade steel , 2015 .

[26]  F. Lu,et al.  Microstructure characteristics and temperature-dependent high cycle fatigue behavior of advanced 9% Cr/CrMoV dissimilarly welded joint , 2014 .

[27]  X. An,et al.  Enhanced cyclic deformation responses of ultrafine-grained Cu and nanocrystalline Cu–Al alloys , 2014 .

[28]  J. Polák,et al.  Mechanisms of extrusion and intrusion formation in fatigued crystalline materials , 2014 .

[29]  Stanisław Mroziński,et al.  Low cycle fatigue and cyclic softening behaviour of martensitic cast steel , 2013 .

[30]  D. McDowell,et al.  Microstructure-sensitive HCF and VHCF simulations , 2013 .

[31]  Tilmann Beck,et al.  Influence of mean stresses on fatigue life and damage of a turbine blade steel in the VHCF-regime , 2013 .

[32]  Ming-Liang Zhu,et al.  Influence of microstructure and microdefects on long-term fatigue behavior of a Cr–Mo–V steel , 2012 .

[33]  Z. F. Zhang,et al.  Fatigue cracking at twin boundaries: Effects of crystallographic orientation and stacking fault energy (vol 60, pg 3113, 2012) , 2012 .

[34]  F. Xuan,et al.  Ratchetting behavior of advanced 9–12% chromium ferrite steel under creep–fatigue loadings: Fracture modes and dislocation patterns , 2012 .

[35]  K. Chan,et al.  Roles of microstructure in fatigue crack initiation , 2010 .

[36]  Toshihiro Shimizu,et al.  Effect of loading condition on very high cycle fatigue behavior in a high strength steel , 2010 .

[37]  Kazuaki Shiozawa,et al.  Very high cycle fatigue properties of bearing steel under axial loading condition , 2009 .

[38]  M. Jahazi,et al.  Strain hardening behavior of a friction stir welded magnesium alloy , 2007 .

[39]  W. Tian,et al.  Diminishing of work hardening in electroformed polycrystalline copper with nano-sized and uf-sized twins , 2006 .

[40]  N. Oguma,et al.  Effect of stress ratio on long life fatigue behavior of high carbon chromium bearing steel under axial loading , 2004 .

[41]  S. Kwofie,et al.  An exponential stress function for predicting fatigue strength and life due to mean stresses , 2001 .

[42]  B. Zhong,et al.  High cycle fatigue characterization of a nickel-based superalloy based on a novel temperature-dependent regression method , 2021 .

[43]  Jianfeng Mao,et al.  Experimental study on creep-fatigue behaviors of chinese P92 steel with consideration of several important factors , 2021 .

[44]  J. Vogt,et al.  The early stage of fatigue crack initiation in a 12%Cr martensitic steel , 2018 .

[45]  F. Xuan,et al.  Effect of temperature on high-cycle fatigue and very high cycle fatigue behaviours of a low-strength Cr–Ni–Mo–V steel welded joint , 2017 .

[46]  Hans-Jürgen Christ,et al.  On the effects of particle strengthening and temperature on the VHCF behavior at high frequency , 2011 .

[47]  E. Hornbogen Martensitic transformation at a propagating crack , 1978 .

[48]  Qasim H. Bader,et al.  Mean Stress Correction Effects On the Fatigue Life Behavior of Steel Alloys by Using Stress Life Approach Theories , 2022 .