Fe−Mn−Al−C high-entropy steels with superior mechanical properties at 4.2 K
暂无分享,去创建一个
Z. Liu | Jun Chen | Siwei Wu | Long Zhang | Weina Zhang | J. Ren | Zhi-hong Li | Jun Chen
[1] Heng Zhang,et al. Simultaneously enhancing strength-ductility synergy and strain hardenability via Si-alloying in medium-Al FeMnAlC lightweight steels , 2022, Acta Materialia.
[2] R. Umretiya,et al. The Relationship Between Grain Size Distribution and Ductile to Brittle Transition Temperature in FeCrAl Alloys , 2022, Materials Letters.
[3] Di Wang,et al. Temperature-dependent dynamic compressive properties and failure mechanisms of the additively manufactured CoCrFeMnNi high entropy alloy , 2022, Materials & Design.
[4] Z. Liu,et al. Quasi-in-situ observations of crack propagation and microstructure evolution of high manganese austenitic steel at −196 °C , 2022, Engineering Fracture Mechanics.
[5] Chaoyue Chen,et al. Strength-ductility synergy of CoCrNi medium-entropy alloy processed with laser powder bed fusion , 2022, Materials & Design.
[6] Shijian Zheng,et al. Dynamically reversible shear transformations in a CrMnFeCoNi high-entropy alloy at cryogenic temperature , 2022, Acta Materialia.
[7] W. Wang,et al. Effect of Co on phase stability and mechanical behavior of CoxCrFeNiMnAl0.3 high entropy alloys with micro/nano hierarchical structure , 2022, Materials & Design.
[8] W. Wang,et al. Mechanical properties and microstructure evolution of cryogenic pre-strained 316LN stainless steel , 2021, Cryogenics.
[9] Qi-yuan Chen,et al. Effect of secondary twins on strain hardening behavior of a high manganese austenitic steel at 77 K by quasi in situ EBSD , 2021, Materials Characterization.
[10] K. Dahmen,et al. Deformation behavior of a Co-Cr-Fe-Ni-Mo medium-entropy alloy at extremely low temperatures , 2021, Materials Today.
[11] Jun Chen,et al. High carbon alloyed design of a hot-rolled high-Mn austenitic steel with excellent mechanical properties for cryogenic application , 2021, Materials Science and Engineering: A.
[12] Jun Chen,et al. Deformation microstructures as well as strengthening and toughening mechanisms of low-density high Mn steels for cryogenic applications , 2021, Journal of Materials Research and Technology.
[13] Yi-Ting Lin,et al. Mechanism of twinning induced plasticity in austenitic lightweight steel driven by compositional complexity , 2021 .
[14] Qi-yuan Chen,et al. Role of vanadium additions on tensile and cryogenic-temperature charpy impact properties in hot-rolled high-Mn austenitic steels , 2021 .
[15] Y. Chiu,et al. Synergistic deformation pathways in a TWIP steel at cryogenic temperatures: In situ neutron diffraction , 2020 .
[16] Peng Chen,et al. The κ-Carbides in Low-Density Fe-Mn-Al-C Steels: A Review on Their Structure, Precipitation and Deformation Mechanism , 2020, Metals.
[17] Jun Chen,et al. Enhancing strength and cryogenic toughness of high manganese TWIP steel plate by double strengthened structure design , 2020 .
[18] T. Hanemann,et al. Comparison of cryogenic deformation of the concentrated solid solutions CoCrFeMnNi, CoCrNi and CoNi , 2020, Materials Science and Engineering: A.
[19] Qi-yuan Chen,et al. On Mechanical Properties of Welded Joint in Novel High-Mn Cryogenic Steel in Terms of Microstructural Evolution and Solute Segregation , 2020, Metals.
[20] Mingxin Huang,et al. The role of interstitial carbon atoms on the strain-hardening rate of twinning-induced plasticity steels , 2020 .
[21] Yuan Wu,et al. Cooperative deformation in high-entropy alloys at ultralow temperatures , 2020, Science Advances.
[22] S. Sohn,et al. Effects of Ni and Cu addition on cryogenic-temperature tensile and Charpy impact properties in austenitic 22Mn-0.45C–1Al steels , 2020 .
[23] F. Yuan,et al. High impact toughness of CrCoNi medium-entropy alloy at liquid-helium temperature , 2019, Scripta Materialia.
[24] R. Ritchie,et al. Mechanical properties of high-entropy alloys with emphasis on face-centered cubic alloys , 2019, Progress in Materials Science.
[25] P. Liaw,et al. Excellent ductility and serration feature of metastable CoCrFeNi high-entropy alloy at extremely low temperatures , 2018, Science China Materials.
[26] Jun Chen,et al. Interpretation of significant decrease in cryogenic-temperature Charpy impact toughness in a high manganese steel , 2018, Materials Science and Engineering: A.
[27] Wei Li,et al. Hierarchical microstructure design of a bimodal grained twinning-induced plasticity steel with excellent cryogenic mechanical properties , 2018, Acta Materialia.
[28] Mingxin Huang,et al. Revisit the role of deformation twins on the work-hardening behaviour of twinning-induced plasticity steels , 2018 .
[29] Y. Estrin,et al. Twinning-induced plasticity (TWIP) steels , 2018 .
[30] K. An,et al. Twinning-mediated work hardening and texture evolution in CrCoFeMnNi high entropy alloys at cryogenic temperature , 2017 .
[31] A. Haldar,et al. Current state of Fe-Mn-Al-C low density steels , 2017 .
[32] Hyoung-Seop Kim,et al. Continuum understanding of twin formation near grain boundaries of FCC metals with low stacking fault energy , 2017, npj Computational Materials.
[33] Dierk Raabe,et al. Ultrastrong steel via minimal lattice misfit and high-density nanoprecipitation , 2017, Nature.
[34] Zijiao Zhang,et al. Dislocation mechanisms and 3D twin architectures generate exceptional strength-ductility-toughness combination in CrCoNi medium-entropy alloy , 2017, Nature Communications.
[35] G. Eggeler,et al. Microstructure evolution and critical stress for twinning in the CrMnFeCoNi high-entropy alloy , 2016 .
[36] P. Mahajan,et al. Effect of Al on Growth Kinetics of Cementite in Fe–C–Al Alloys , 2016 .
[37] Huajian Gao,et al. Nanotwin-governed toughening mechanism in hierarchically structured biological materials , 2016, Nature Communications.
[38] Jian‐Jun Zheng,et al. Strain hardening behavior and deformation substructure of Fe–20/27Mn–4Al–0.3C non-magnetic steels , 2016 .
[39] Bernd Gludovatz,et al. Exceptional damage-tolerance of a medium-entropy alloy CrCoNi at cryogenic temperatures , 2016, Nature Communications.
[40] Robert O. Ritchie,et al. Nanoscale origins of the damage tolerance of the high-entropy alloy CrMnFeCoNi , 2015, Nature Communications.
[41] D. Raabe,et al. The influence of stacking fault energy on the microstructural and strain-hardening evolution of Fe–Mn–Al–Si steels during tensile deformation , 2015 .
[42] Dierk Raabe,et al. From High‐Entropy Alloys to High‐Entropy Steels , 2015 .
[43] T. Yamazaki,et al. Effect of Change of Aging Heat Treatment Pattern on the JK2LB Jacket for the ITER Central Solenoid , 2015 .
[44] T. Yamazaki,et al. Mechanical Properties of High Manganese Austenitic Stainless Steel JK2LB for ITER Central Solenoid Jacket Material , 2015 .
[45] R. Ritchie,et al. A fracture-resistant high-entropy alloy for cryogenic applications , 2014, Science.
[46] Yuehua Wu,et al. Mechanical tensile test of the full-size ITER TF conductor jacket materials at 4.2 K , 2013 .
[47] S. Sgobba,et al. A comparative assessment of metallurgical and mechanical properties of two austenitic stainless steels for the conductor jacket of the ITER Central Solenoid , 2013 .
[48] Peter K. Liaw,et al. Mechanical properties of the high-entropy alloy Ag0.5CoCrCuFeNi at temperatures of 4.2–300 K , 2013 .
[49] 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 .
[50] D. Raabe,et al. Influence of Al content and precipitation state on the mechanical behavior of austenitic high-Mn low , 2013 .
[51] D. Raabe,et al. Multistage strain hardening through dislocation substructure and twinning in a high strength and duc , 2012 .
[52] Paul Libeyre,et al. Fatigue crack growth rate and fracture toughness of ITER central solenoid jacket materials at 7 K , 2012 .
[53] P. Libeyre,et al. Progress in Production and Qualification of Stainless Steel Jacket Material for the Conductor of the ITER Central Solenoid , 2012, IEEE Transactions on Applied Superconductivity.
[54] R. Ritchie. The conflicts between strength and toughness. , 2011, Nature materials.
[55] V. Kuokkala,et al. Thermodynamic modeling of the stacking fault energy of austenitic steels , 2011 .
[56] V. Kuokkala,et al. Dependence of tensile deformation behavior of TWIP steels on stacking fault energy, temperature and strain rate , 2010 .
[57] J. Miller,et al. MECHANICAL PROPERTIES OF MODIFIED JK2LB FOR Nb3Sn CICC APPLICATIONS , 2010 .
[58] Kyung-Tae Park,et al. Origin of Extended Tensile Ductility of a Fe-28Mn-10Al-1C Steel , 2009 .
[59] J. G. Sevillano. An alternative model for the strain hardening of FCC alloys that twin, validated for twinning-induced plasticity steel , 2009 .
[60] Kyung-Tae Park,et al. Microband-induced plasticity in a high Mn–Al–C light steel , 2008 .
[61] O. Bouaziz,et al. Influence of addition elements on the stacking-fault energy and mechanical properties of an austenitic Fe–Mn–C steel , 2008 .
[62] O. Bouaziz,et al. Effect of grain and twin boundaries on the hardening mechanisms of twinning-induced plasticity steels , 2008 .
[63] Y. Shindo,et al. Cryogenic fracture and adiabatic heating of austenitic stainless steels for superconducting fusion magnets , 2003 .
[64] Young‐kook Lee,et al. Driving force for γ→ε martensitic transformation and stacking fault energy of γ in Fe-Mn binary system , 2000 .
[65] H. Fujimura,et al. Local interactions in carbon-carbon and carbon-M (M: Al, Mn, Ni) atomic pairs in FCC gamma -iron , 1994 .
[66] R. Reed,et al. Heating Effects During Tensile Tests of Aisi 304L Stainless Steel At 4 K , 1980 .
[67] C. Syn,et al. Cryogenic fracture toughness of 9Ni Steel enhanced through grain refinement , 1976 .
[68] R. A. Clark,et al. The effect of austenitizing temperature on the microstructure and mechanical properties of as-quenched 4340 steel , 1974, Metallurgical and Materials Transactions B.
[69] S. TOLANSKY,et al. Dislocations , 1966, Nature.