TiN refinement and resultant grain refinement in magnesium-treated ultra-pure ferritic stainless steel
暂无分享,去创建一个
Tian-peng Qu | Dong Hou | Jun Tian | Xingzhi Zhou | Deyong Wang | Zhi‐Xiao Zhang | Yanping Wang | Xiang-Long Li | De-yong Wang | Tian‐Peng Qu
[1] Jun Tian,et al. Refining mechanism for TiN and solidification structure through a nucleating chain in magnesium-yttrium-treated ultrapure ferritic stainless steel , 2023, Journal of Materials Research and Technology.
[2] Xianglong Li,et al. Mechanism for TiN refinement and resultant heterogeneous nucleation of δ-Fe in magnesium-rare earth-treated ultrapure ferritic stainless steel , 2023, Materials Characterization.
[3] Yuyang Hou,et al. Acceleration Mechanism of Ti2o3 on Tin Formation and Δ-Ferrite Nucleation of Ferritic Stainless Steel , 2022, SSRN Electronic Journal.
[4] De-yong Wang,et al. Interface characteristics between TiN and matrix and their effect on solidification structure , 2021, Journal of Iron and Steel Research International.
[5] J. Zollinger,et al. Effect of Direct Powder Additions on the Solidification Structure and Microsegregation of 42CrMo4 Steel , 2020, ISIJ International.
[6] M. X. Zhang,et al. Grain Refinement Mechanism of the δ-Ferrite in Steels Through Cerium Addition , 2020, Metallurgical and Materials Transactions A.
[7] Yuyang Hou,et al. Effect of Oxide Composition on the Orientation Relationship and Disregistry in Complex Nucleus of Ti and Nb Stabilized Ferritic Stainless Steel Revealed by EBSD Measurement , 2020, Metallurgical and Materials Transactions B.
[8] Yuyang Hou,et al. Effects of Nucleus Density and Dendritic Growth Influenced by Ti and Nb on Solidification Structure of Fe-18 Pct Cr Ferritic Stainless Steel , 2019, Metallurgical and Materials Transactions B.
[9] M. Zhang,et al. Crystallography of the Heterogeneous Nucleation of δ-Ferrite on Ce2O2S Particles During Solidification of an Fe-4Si Alloy , 2019, Metallurgical and Materials Transactions A.
[10] Yuyang Hou,et al. Effect of Nb on the As-cast Structure and Compactness Degree of Ferritic Stainless Steel Dual Stabilized by Ti and Nb , 2018, ISIJ International.
[11] Z. Fan,et al. A new concept for growth restriction during solidification , 2018 .
[12] J. Park,et al. Synergistic Effect of Nitrogen and Refractory Material on TiN Formation and Equiaxed Grain Structure of Ferritic Stainless Steel , 2018, Metallurgical and Materials Transactions B.
[13] Yucheng Wu,et al. Crystallography and growth mechanism of TiN in Fe-17Cr stainless steel during solidification , 2018 .
[14] Y. H. Oh,et al. Hetero-epitaxial nucleation of ferrite at a TiN encapsulating MgAl2O4 during rapid solidification in a newly developed ferritic stainless steel , 2017 .
[15] J. Park,et al. TEM characterization of a TiN-MgAl2O4 epitaxial interface , 2017 .
[16] T. K. Radhakrishnan,et al. A Review of Classical and Nonclassical Nucleation Theories , 2016 .
[17] Haiyang Li,et al. Mathematical Modeling on the Growth and Removal of Non-metallic Inclusions in the Molten Steel in a Two-Strand Continuous Casting Tundish , 2016, Metallurgical and Materials Transactions B.
[18] D. Qiu,et al. The influence of CaO addition on grain refinement of cast magnesium alloys , 2016 .
[19] Ma Qian,et al. Recent advances in grain refinement of light metals and alloys , 2016 .
[20] S. Michelic,et al. Characterization of TiN, TiC and Ti(C,N) in titanium-alloyed ferritic chromium steels focusing on the significance of different particle morphologies , 2015 .
[21] D. Qiu,et al. Current research progress in grain refinement of cast magnesium alloys: A review article , 2015 .
[22] J. Park,et al. Effect of Mg–Ti Deoxidation on the Formation Behavior of Equiaxed Crystals During Rapid Solidification of Iron Alloys , 2014 .
[23] Ke Liu,et al. Precipitation of metastable phases and its effect on electrical resistivity of Al-0.96Mg2Si alloy during aging , 2014 .
[24] D. Shu,et al. Effects of Mg Addition on Inclusions Formation and Resultant Solidification Structure Changes of Ti-stabilized Ultra-pure Ferritic Stainless Steel , 2014 .
[25] Mingxing Zhang,et al. Effect of Mg24Y5 intermetallic particles on grain refinement of Mg-9Li alloy , 2014 .
[26] A. Takahashi,et al. Effect of Mg Addition on Equiaxed Grain Formation in Ferritic Stainless Steel , 2013 .
[27] Merton C. Flemings,et al. Grain refinement behavior of an aluminum alloy by inoculation and dynamic nucleation , 2013 .
[28] J. Park,et al. Effect of Complex Inclusion Particles on the Solidification Structure of Fe-Ni-Mn-Mo Alloy , 2012, Metallurgical and Materials Transactions B.
[29] Akihisa Ito,et al. Size Distribution of Multi-phase Deoxidation Particles for Heterogeneous Crystallization of TiN and Solidification Structure in Ti-Added Ferritic Stainless Steel , 2012 .
[30] Xiaoqiang Hu,et al. Mechanisms of Solidification Structure Improvement of Ultra Pure 17 wt% Cr Ferritic Stainless Steel by Ti, Nb Addition , 2011 .
[31] Kohichi Isobe,et al. Effect of Mg Addition on Solidification Structure of Low Carbon Steel , 2010 .
[32] R. Tuttle. Examination of Steel Castings for Potential Nucleation Phases , 2010 .
[33] Robert E. Peale,et al. Surface and grain-boundary scattering in nanometric Cu films , 2010 .
[34] D. Qiu,et al. Effect of active heterogeneous nucleation particles on the grain refining efficiency in an Mg-10 wt.% Y cast alloy , 2009 .
[35] A. Karasev,et al. On the Role of Non-metallic Inclusions in the Nucleation of Acicular Ferrite in Steels , 2009 .
[36] M. Zehetbauer,et al. The presence and nature of vacancy type defects in nanometals detained by severe plastic deformation , 2008 .
[37] M. Bermingham,et al. Effects of boron on microstructure in cast titanium alloys , 2008 .
[38] D. Lloyd,et al. A study on the early-stage decomposition in the Al–Mg–Si–Cu alloy AA6111 by electrical resistivity and three-dimensional atom probe , 2007 .
[39] Joachim Fischer,et al. Determination of the Boltzmann constant—status and prospects , 2006 .
[40] Surendra P. Shah,et al. Detecting Corrosion Resistance Of Coated Steel Rebars By Electrochemical Technique (Eis) , 2006 .
[41] M. Hayashi,et al. Effect of catalyst on heterogeneous nucleation in Fe-Ni-Cr alloys , 2006 .
[42] H. Ohta,et al. Effect of oxide catalyst on heterogeneous nucleation in Fe-10mass%Ni alloys , 2006 .
[43] D. Lloyd,et al. Analysis of ridging in ferritic stainless steel sheet , 2006 .
[44] D. Lloyd,et al. Examination of precipitation in the aluminum alloy AA6111 using electrical resistivity measurements , 2006 .
[45] Patrick M. Kelly,et al. Edge-to-edge matching—The fundamentals , 2006 .
[46] C. Tomé,et al. Crystal-plasticity analysis of ridging in ferritic stainless steel sheets , 2005 .
[47] D. StJohn,et al. Grain refinement of magnesium alloys , 2005 .
[48] M. Easton,et al. Crystallographic study of grain refinement in aluminum alloys using the edge-to-edge matching model , 2005 .
[49] Mingxing Zhang,et al. Edge-to-edge matching and its applications: Part II. Application to Mg–Al, Mg–Y and Mg–Mn alloys , 2005 .
[50] Patrick M. Kelly,et al. Edge-to-edge matching and its applications: Part I. Application to the simple HCP/BCC system , 2005 .
[51] A. L. Greer,et al. The effect of the size distribution of inoculant particles on as-cast grain size in aluminium alloys , 2004 .
[52] D. StJohn,et al. Heterogeneous nuclei size in magnesium-zirconium alloys , 2004 .
[53] Y. Matsumoto,et al. Effect of Initial Solidified Structure on Ridging Phenomenon and Texture in Type 430 Ferritic Stainless Steel Sheets , 2003 .
[54] K. Nakajima,et al. Effect of a catalyst on heterogeneous nucleation in pure and Fe-Ni alloys , 2003 .
[55] Dong Nyung Lee,et al. The effect of texture on ridging of ferritic stainless steel , 2003 .
[56] R. Knutsen,et al. Modelling surface ridging in ferritic stainless steel , 2002 .
[57] Kyu Young Kim,et al. Evolution of Microstructure and Texture Associated with Ridging in Ferritic Stainless Steels , 2002 .
[58] P. Becker,et al. History and progress in the accurate determination of the Avogadro constant , 2001 .
[59] T. Chandrashekar,et al. Effects and mechanisms of grain refinement in aluminium alloys , 2001 .
[60] H. Suito,et al. Effect of Primary Deoxidation Products of Al2O3, ZrO2, Ce2O3 and MgO on TiN Precipitation in Fe–10mass%Ni Alloy , 2001 .
[61] Moo Young Huh,et al. Effect of intermediate annealing on texture, formability and ridging of 17%Cr ferritic stainless steel sheet , 2001 .
[62] B. Verlinden,et al. Quantification of volume fraction of precipitates in an aged Al-1.0 mass%Mg2Si alloy , 2000 .
[63] I. Gutiérrez,et al. Role of the particle–matrix interface on the nucleation of acicular ferrite in a medium carbon microalloyed steel , 1999 .
[64] P. T. Olsen,et al. Accurate Measurement of the Planck Constant , 1998 .
[65] A. S. Karolik,et al. Calculation of electrical resistivity produced by dislocations and grain boundaries in metals , 1994 .
[66] K. Nogi,et al. Surface Tension of Molten Fe-O-S Alloy , 1983 .
[67] K. Asano,et al. Effect of Oxides on Nucleation Behaviour in Supercooled Iron , 1976 .
[68] A. Hellawell,et al. An analysis of the peritectic reaction with particular reference to Al-Ti alloys , 1975 .
[69] A. Hellawell,et al. A simple model for grain refinement during solidification , 1974 .
[70] T. Endo,et al. Deviations from Matthiessen's Rule of the Electrical Resistivity of Dislocations in Aluminum , 1974 .
[71] H. Chao. Recent studies into the mechanism of ridging in ferritic stainless steels , 1973 .
[72] J. Dugdale,et al. Mathiessen's Rule and Anisotropic Relaxation Times , 1967 .
[73] H. L. Johnston,et al. FORMATION, STABILITY AND CRYSTAL STRUCTURE OF THE SOLID ALUMINUM SUBOXIDES: A12/ AND A1/ , 1954 .
[74] G. E. Jauncey,et al. The Scattering of X-Rays and Bragg's Law. , 1924, Proceedings of the National Academy of Sciences of the United States of America.
[75] T. Matsumiya,et al. Comparison between the Capability of MgO and that of TiN on the Heterogeneous Nucleation of δ-Fe Containing 0.05 mass%C , 2019, Tetsu-to-Hagane.
[76] T. Matsumiya,et al. Effect of ZrO2 on the Heterogeneous Nucleation of γ-Fe Containing 0.75 mass%C , 2019, Tetsu-to-Hagane.
[77] M. Easton,et al. The Influence of the Effect of Solute on the Thermodynamic Driving Force on Grain Refinement of Al Alloys , 2014, Metallurgical and Materials Transactions A.
[78] D. StJohn,et al. An analysis of the relationship between grain size, solute content, and the potency and number density of nucleant particles , 2005 .
[79] K. Bhanumurthy,et al. Intermetallics in the Zr–Al diffusion zone , 2004 .
[80] K. Cashman. Relationship between plagioclase crystallization and cooling rate in basaltic melts , 1993 .
[81] Wu,et al. Experimental demonstration of the role of local latent heat in Ge pattern formation. , 1990, Physical review. B, Condensed matter.
[82] W. A. Miller,et al. Calculation of the Crystal-Melt Interfacial Free Energy from Experimental Radial Distribution Function Data , 1978 .
[83] K. Kawahara. Effect of Solidification Structure on the Ridging Phenomena in 17Cr Stainless Steels , 1974 .
[84] B. L. Bramfitt. The effect of carbide and nitride additions on the heterogeneous nucleation behavior of liquid iron , 1970 .
[85] U. R. Evans. The laws of expanding circles and spheres in relation to the lateral growth of surface films and the grain-size of metals , 1945 .