Effect of cutting method on hydrogen embrittlement of high-Mn TWIP steel
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[1] M. Koyama,et al. High-concentration carbon assists plasticity-driven hydrogen embrittlement in a Fe-high Mn steel with a relatively high stacking fault energy , 2018 .
[2] Mingxing Zhang,et al. The role of the microstructure on the influence of hydrogen on some advanced high-strength steels , 2018 .
[3] Jianzhong Zhou,et al. Influence of laser peening on the hydrogen embrittlement resistance of 316L stainless steel , 2017 .
[4] Mingxing Zhang,et al. Hydrogen influence on some advanced high-strength steels , 2017 .
[5] Oreste S. Bursi,et al. Laser and mechanical cutting effects on the cut-edge properties of steel S355N , 2017 .
[6] P. Rivera-Díaz-del-Castillo,et al. Understanding martensite and twin formation in austenitic steels: A model describing TRIP and TWIP effects , 2017 .
[7] Taekyung Lee,et al. Effect of Al addition on low-cycle fatigue properties of hydrogen-charged high-Mn TWIP steels , 2016 .
[8] H. Maier,et al. Effect of strain rate on hydrogen embrittlement susceptibility of twinning-induced plasticity steel pre-charged with high-pressure hydrogen gas , 2016 .
[9] M. Koyama,et al. Hydrogen Embrittlement Susceptibility of Fe-Mn Binary Alloys with High Mn Content: Effects of Stable and Metastable ε-Martensite, and Mn Concentration , 2016, Metallurgical and Materials Transactions A.
[10] N. Tsuji,et al. Effect of grain refinement on hydrogen embrittlement behaviors of high-Mn TWIP steel , 2016 .
[11] W. Bleck,et al. Effects of grain size on hydrogen embrittlement in a Fe-22Mn-0.6C TWIP steel , 2015 .
[12] Young-Soo Chun,et al. Role of Cu on hydrogen embrittlement behavior in Fe–Mn–C–Cu TWIP steel , 2015 .
[13] Hyunkyu Jeon,et al. The advantage of grain refinement in the hydrogen embrittlement of Fe–18Mn–0.6C twinning-induced plasticity steel , 2015 .
[14] Young‐kook Lee,et al. The effect of Ti precipitates on hydrogen embrittlement of Fe–18Mn–0.6C–2Al–xTi twinning-induced plasticity steel , 2014 .
[15] X. M. Chen,et al. Edge cracking mechanism in two dual-phase advanced high strength steels , 2014 .
[16] Todd M. Mower,et al. Degradation of titanium 6Al–4V fatigue strength due to electrical discharge machining , 2014 .
[17] J. Lesage,et al. X-ray diffraction study of microstructural changes during fatigue damage initiation in pipe steels: Role of the initial dislocation structure , 2013 .
[18] M. Koyama,et al. Hydrogen-assisted failure in a twinning-induced plasticity steel studied under in situ hydrogen char , 2013 .
[19] Chun‐Sing Lee,et al. Delayed static failure of twinning-induced plasticity steels , 2012 .
[20] Young‐kook Lee,et al. The mechanism of enhanced resistance to the hydrogen delayed fracture in Al-added Fe–18Mn–0.6C twinning-induced plasticity steels , 2012 .
[21] M. Koyama,et al. Effect of hydrogen content on the embrittlement in a Fe–Mn–C twinning-induced plasticity steel , 2012 .
[22] A. Deschamps,et al. Hydrogen trapping by VC precipitates and structural defects in a high strength Fe–Mn–C steel studied by small-angle neutron scattering , 2012 .
[23] O. Takakuwa,et al. Numerical simulation of the effects of residual stress on the concentration of hydrogen around a crack tip , 2012 .
[24] Young-Soo Chun,et al. Role of ɛ martensite in tensile properties and hydrogen degradation of high-Mn steels , 2012 .
[25] Helmut Schaeben,et al. Grain detection from 2d and 3d EBSD data--specification of the MTEX algorithm. , 2011, Ultramicroscopy.
[26] O. Bouaziz,et al. High manganese austenitic twinning induced plasticity steels: A review of the microstructure properties relationships , 2011 .
[27] Sunghak Lee,et al. Effects of Al addition on deformation and fracture mechanisms in two high manganese TWIP steels , 2011 .
[28] Mark Whittaker,et al. The influence of mechanical and CO2 laser cut-edge characteristics on the fatigue life performance of high strength automotive steels , 2011 .
[29] Janet Folkes,et al. Waterjet—An innovative tool for manufacturing , 2009 .
[30] Daniel J. Thomas. Characteristics of abrasive waterjet cut-edges and the affect on formability and fatigue performance of high strength steels , 2009 .
[31] Jacques Besson,et al. Effect of shear cutting on ductility of a dual phase steel , 2009 .
[32] S. Yao,et al. Microstructure analysis of the martensitic stainless steel surface fine-cut by the wire electrode discharge machining (WEDM) , 2004 .
[33] Y. Estrin,et al. Twinning-induced plasticity (TWIP) steels , 2018 .
[34] M. Koyama,et al. Spatially and Kinetically Resolved Mapping of Hydrogen in a Twinning-Induced Plasticity Steel by Use of Scanning Kelvin Probe Force Microscopy , 2015 .
[35] Dierk Raabe,et al. Revealing the strain-hardening behavior of twinning-induced plasticity steels: Theory, simulations, , 2013 .
[36] M. Koyama,et al. Hydrogen embrittlement in a Fe–Mn–C ternary twinning-induced plasticity steel , 2012 .
[37] Kwansoo Chung,et al. Formability of TWIP (twinning induced plasticity) automotive sheets , 2011 .