Alleviating the strength-ductility trade-off dilemma in high manganese steels after hydrogen charging by adjusting the gradient distribution of twins

[1]  S. Antonov,et al.  Effect of pre-strain on hydrogen embrittlement of high manganese steel , 2022, Materials Science and Engineering: A.

[2]  Yanjing Su,et al.  Twinning behavior and hydrogen embrittlement of a pre-strained twinning-induced plasticity (TWIP) steel , 2021 .

[3]  Yanjing Su,et al.  Outstanding Tensile Properties and Their Origins in Twinning-Induced Plasticity (TWIP) Steels with Gradient Substructures , 2020, Materials.

[4]  Zixuan Yang,et al.  Stress-induced hydrogen redistribution and corresponding fracture behavior of Q960E steel at different hydrogen content , 2020 .

[5]  E. Han,et al.  Effect of grain refinement on the hydrogen embrittlement of 304 austenitic stainless steel , 2019, Journal of Materials Science & Technology.

[6]  R.Z. Wang,et al.  Hydrogen embrittlement sensitivity of X100 pipeline steel under different pre-strain , 2019, International Journal of Hydrogen Energy.

[7]  L. Lu,et al.  A nanotwinned austenite stainless steel with high hydrogen embrittlement resistance , 2019, Journal of Alloys and Compounds.

[8]  Xiaogang Li,et al.  Effect of pre-strain on microstructure and hydrogen embrittlement of K-TIG welded austenitic stainless steel , 2019, Corrosion Science.

[9]  Cheolho Park,et al.  Effect of Prestrain on Hydrogen Embrittlement Susceptibility of EH 36 Steels Using In Situ Slow-Strain-Rate Testing , 2018, Metals and Materials International.

[10]  S. Suwas,et al.  A novel way to enhance the strength of twinning induced plasticity (TWIP) steels , 2018, Scripta Materialia.

[11]  Heung Nam Han,et al.  Influence of pre-strain on the gaseous hydrogen embrittlement resistance of a high-entropy alloy , 2018 .

[12]  Z. Zhang,et al.  Simultaneous improvement of strength and plasticity: Additional work-hardening from gradient microstructure , 2018 .

[13]  P. Zhou,et al.  Improving hydrogen embrittlement resistance of Hadfield steel by thermo-mechanical flash-treatment , 2018 .

[14]  Cheolho Park,et al.  Effect of grain size on the resistance to hydrogen embrittlement of API 2W Grade 60 steels using in situ slow-strain-rate testing , 2017 .

[15]  B. D. Cooman,et al.  Stacking fault energy and deformation mechanisms in Fe-xMn-0.6C-yAl TWIP steel , 2016 .

[16]  Tingting Liu,et al.  Enhancing tensile strength of Cu by introducing gradient microstructures via a simple torsion deformation , 2016 .

[17]  N. Tsuji,et al.  Effect of grain refinement on hydrogen embrittlement behaviors of high-Mn TWIP steel , 2016 .

[18]  Il-Heon Son,et al.  Microstructural evolution and deformation behavior of twinning-induced plasticity (TWIP) steel during wire drawing , 2015 .

[19]  J. McDermid,et al.  Effect of carbon content on the mechanical properties and microstructural evolution of Fe–22Mn–C steels , 2015 .

[20]  Xiaowei Wang,et al.  Hydrogen embrittlement of catholically hydrogen-precharged 304L austenitic stainless steel: Effect of plastic pre-strain , 2014 .

[21]  Young‐kook Lee,et al.  The effect of pre-strain on hydrogen embrittlement in 310S stainless steel , 2014 .

[22]  Huajian Gao,et al.  Evading the strength–ductility trade-off dilemma in steel through gradient hierarchical nanotwins , 2014, Nature Communications.

[23]  M. Koyama,et al.  Hydrogen-assisted failure in a twinning-induced plasticity steel studied under in situ hydrogen char , 2013 .

[24]  Singon Kang,et al.  The effects of Si on the mechanical twinning and strain hardening of Fe-18Mn-0.6C twinning-induced plasticity steel , 2013 .

[25]  M. Koyama,et al.  TWIP Effect and Plastic Instability Condition in an Fe-Mn-C Austenitic Steel , 2013 .

[26]  D. Suh,et al.  Effect of aluminium on hydrogen-induced fracture behaviour in austenitic Fe–Mn–C steel , 2013, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[27]  P. Jacques,et al.  On the relationship between work hardening and twinning rate in TWIP steels , 2012 .

[28]  M. Koyama,et al.  Hydrogen-induced cracking at grain and twin boundaries in an Fe–Mn–C austenitic steel , 2012 .

[29]  N. Ishikawa,et al.  Effects of grain size and dislocation density on the susceptibility to high-pressure hydrogen environment embrittlement of high-strength low-alloy steels , 2012 .

[30]  O. Bouaziz,et al.  High manganese austenitic twinning induced plasticity steels: A review of the microstructure properties relationships , 2011 .

[31]  Jian Lu,et al.  The influence of strain rate on the microstructure transition of 304 stainless steel , 2011 .

[32]  M. Itakura,et al.  First-Principles Study on the Grain Boundary Embrittlement of Metals by Solute Segregation: Part II. Metal (Fe, Al, Cu)-Hydrogen (H) Systems , 2011 .

[33]  M. Robinson,et al.  Hydrogen transport and embrittlement in 300 M and AerMet100 ultra high strength steels , 2010 .

[34]  R. Ritchie,et al.  Grain-boundary engineering markedly reduces susceptibility to intergranular hydrogen embrittlement in metallic materials , 2009 .

[35]  K. Lu,et al.  Strengthening Materials by Engineering Coherent Internal Boundaries at the Nanoscale , 2009, Science.

[36]  O. Bouaziz,et al.  Influence of addition elements on the stacking-fault energy and mechanical properties of an austenitic Fe–Mn–C steel , 2008 .

[37]  O. Bouaziz,et al.  Effect of grain and twin boundaries on the hardening mechanisms of twinning-induced plasticity steels , 2008 .

[38]  R. Kirchheim Reducing grain boundary, dislocation line and vacancy formation energies by solute segregation , 2007 .

[39]  K. Tsuzaki,et al.  Hydrogen degradation of a boron-bearing steel with 1050 and 1300MPa strength levels , 2005 .

[40]  O. Bouaziz,et al.  A physical model of the twinning-induced plasticity effect in a high manganese austenitic steel , 2004 .

[41]  S. Kuramoto,et al.  Recent Development in Hydrogen Microprint Technique and Its Application to Hydrogen Embrittlement , 2003 .

[42]  O. Bouaziz,et al.  Modelling of TWIP effect on work-hardening , 2001 .

[43]  P. Ferreira,et al.  Hydrogen effects on the interaction between dislocations , 1998 .

[44]  Petros Athanasios Sofronis,et al.  Hydrogen-enhanced localized plasticity—a mechanism for hydrogen-related fracture , 1993 .

[45]  Yanjing Su,et al.  Hydrogen-enhanced densified twinning (HEDT) in a twinning-induced plasticity (TWIP) steel , 2021, Scripta Materialia.

[46]  D. Wan,et al.  Effect of hydrogen on the embrittlement susceptibility of Fe–22Mn-0.6C TWIP steel revealed by in-situ tensile tests , 2021 .

[47]  M. Koyama,et al.  Hydrogen embrittlement in a Fe–Mn–C ternary twinning-induced plasticity steel , 2012 .

[48]  Y. Murakami,et al.  Hydrogen transport in solution-treated and pre-strained austenitic stainless steels and its role in hydrogen-enhanced fatigue crack growth , 2009 .

[49]  Chu Wuyang THE EFFECTS OF PLASTIC DEFORMATION ON HYDROGEN INDUCED CRACKING , 2000 .