Publications by Peter Hedström
Peer reviewed
Articles
[1]
T. Fischer et al., "3D micromechanical interaction of thin-film retained austenite and lath martensite by computational plasticity," Scripta Materialia, vol. 256, 2025.
[2]
Z.-S. Xu, M. Bonvalet Rolland and P. Hedström, "A new model for precipitation kinetics considering diffusion within the precipitates," Calphad, vol. 87, 2024.
[3]
J. Kumpati et al., "Deconstructing the Retained Austenite Stability: In Situ Observations on the Austenite Stability in One- and Two-Phase Bulk Microstructures During Uniaxial Tensile Tests," Metallurgical and Materials Transactions. A, vol. 55, no. 11, pp. 4600-4612, 2024.
[4]
T. Loaiza et al., "Micromechanical response of dual-hardening martensitic bearing steel before and after rolling contact fatigue," Journal of Materials Research and Technology, vol. 29, pp. 4728-4734, 2024.
[5]
T. Loaiza et al., "Microstructural decay of matrix and precipitates during rolling contact fatigue in a martensitic dual-hardening bearing steel," Materials & design, vol. 244, 2024.
[6]
N. Heshmati et al., "Microstructural influences on simultaneous strength and fatigue crack resistance in advanced high-strength steels," International Journal of Fatigue, vol. 184, 2024.
[7]
Y. Yuan et al., "On the divergent effects of stress on the self-organizing nanostructure due to spinodal decomposition in duplex stainless steel," Materials Science & Engineering : A, vol. 898, 2024.
[8]
T. Fischer et al., "Relating stress/strain heterogeneity to lath martensite strength by experiments and dislocation density-based crystal plasticity," International journal of plasticity, vol. 174, 2024.
[9]
M. M. Hoseini-Athar, M. Ersson and P. Hedström, "Towards implementation of alloy-specific thermo-fluid modelling for laser powder-bed fusion of Mg alloys," JOURNAL OF MAGNESIUM AND ALLOYS, vol. 12, no. 6, pp. 2327-2344, 2024.
[10]
T. Zhou et al., "Computational thermodynamics and kinetics-guided re-engineering of a high-performance tool steel," Scripta Materialia, vol. 232, 2023.
[11]
N. Heshmati et al., "Correlation between microstructure and fatigue properties of hot-rolled thick-plate complex-phase steel," Materials Science & Engineering : A, vol. 885, 2023.
[12]
S. Sten et al., "Development of a functional hardness gradient in WC-TiC-Co cemented carbide during gradient sintering," International journal of refractory metals & hard materials, vol. 115, 2023.
[13]
T. Kohne et al., "Evolution of Martensite Tetragonality in High-Carbon Steels Revealed by In Situ High-Energy X-Ray Diffraction," Metallurgical and Materials Transactions. A, vol. 54, no. 4, pp. 1083-1100, 2023.
[14]
G. Yang et al., "Heterogeneous grain size and enhanced hardness by precipitation of the BCC particles in medium entropy Fe-Ni-Cr alloys," Journal of Alloys and Compounds, vol. 931, 2023.
[15]
H.-H. König et al., "MiniMelt : An instrument for real-time tracking of electron beam additive manufacturing using synchrotron x-ray techniques," Review of Scientific Instruments, vol. 94, no. 12, 2023.
[16]
T. Loaiza et al., "Refining the mechanistic understanding of microstructural decay during rolling contact fatigue in 52100 bearing steel tempered at high temperature," Journal of Materials Science, pp. 1-20, 2023.
[17]
E. Claesson, H. Magnusson and P. Hedström, "Scanning precession electron diffraction study of carbide precipitation sequence in low alloy martensitic Cr-Mo-V tool steel," Materials Characterization, vol. 202, 2023.
[18]
T. Fischer, C. F. O. Dahlberg and P. Hedström, "Sensitivity of local cyclic deformation in lath martensite to flow rule and slip system in crystal plasticity," Computational materials science, vol. 222, pp. 112106, 2023.
[19]
C. Wang et al., "A generic and extensible model for the martensite start temperature incorporating thermodynamic data mining and deep learning framework," Journal of Materials Science & Technology, vol. 128, pp. 31-43, 2022.
[20]
E. Claesson et al., "Carbide Precipitation during Processing of Two Low-Alloyed Martensitic Tool Steels with 0.11 and 0.17 V/Mo Ratios Studied by Neutron Scattering, Electron Microscopy and Atom Probe," Metals, vol. 12, no. 5, pp. 758-758, 2022.
[21]
F. Sayari et al., "Comparison of the effect of ECAP and SSE on microstructure, texture, and mechanical properties of magnesium," Journal of Alloys and Compounds, vol. 908, 2022.
[22]
P. Croné et al., "Continuum plasticity modelling of work hardening for precipitation-hardened martensitic steel guided by atom probe tomography," Materials & design, vol. 215, 2022.
[23]
B. Neding et al., "Correlating temperature-dependent stacking fault energy and in-situ bulk deformation behavior for a metastable austenitic stainless steel," Materials Science & Engineering : A, vol. 832, pp. 142403, 2022.
[24]
T. Kohne et al., "Correlation of Heterogeneous Local Martensite Tetragonality and Carbon Distribution in High Carbon Steel," Materials, vol. 15, no. 19, pp. 6653, 2022.
[25]
T. Fischer et al., "Creep-fatigue properties of austenitic cast iron D5S with tension and compression dwell : A dislocation density-based crystal plasticity study," Materials Science & Engineering : A, vol. 860, pp. 144212, 2022.
[26]
A. B. Yildiz et al., "Design, synthesis, structure, and stability of novel multi-principal element (Ti,Zr,Hf,W)C ceramic with a miscibility gap," Journal of the European Ceramic Society, vol. 42, no. 11, pp. 4429-4435, 2022.
[27]
T. Kohne et al., "Early Martensitic Transformation in a 0.74C–1.15Mn–1.08Cr High Carbon Steel," Metallurgical and Materials Transactions. A, vol. 53, no. 8, pp. 3034-3043, 2022.
[28]
A. Ståhlkrantz et al., "Effect of Carbon Content on Variant Pairing in Bainitic Low Alloy Steel," Metallurgical and Materials Transactions. A, vol. 53, no. 9, pp. 3418-3427, 2022.
[29]
J. Liu et al., "Effect of Cooling Rate after Solution Treatment on Subsequent Phase Separation Evolution in Super Duplex Stainless Steel 25Cr-7Ni (wt.%)," Metals, vol. 12, no. 5, pp. 890, 2022.
[30]
S. Lin et al., "Effect of Si on bainitic transformation kinetics in steels explained by carbon partitioning, carbide formation, dislocation densities, and thermodynamic conditions," Materials Characterization, vol. 185, 2022.
[31]
A. Dahlström et al., "Effect of Stress on Spinodal Decomposition in Binary Alloys : Atomistic Modeling and Atom Probe Tomography," Metallurgical and Materials Transactions. A, vol. 53, no. 1, pp. 39-49, 2022.
[32]
E. Claesson et al., "Evolution of iron carbides during tempering of low-alloy tool steel studied with polarized small angle neutron scattering, electron microscopy and atom probe," Materials Characterization, vol. 194, pp. 112464-112464, 2022.
[33]
T. Kohne et al., "Impact of Cooling Rate during High-Pressure Gas Quenching on Fatigue Performance of Low Pressure Carburized Gears," Metals, vol. 12, no. 11, pp. 1917-1917, 2022.
[34]
C. Ioannidou et al., "In-situ synchrotron X-ray analysis of metal Additive Manufacturing : Current state, opportunities and challenges," Materials & design, vol. 219, pp. 110790, 2022.
[35]
W. Zhao et al., "Initial atmospheric corrosion studies of copper from macroscale to nanoscale in a simulated indoor atmospheric environment," Corrosion Science, vol. 195, 2022.
[36]
T. Zhou et al., "Microstructure control during deposition and post-treatment to optimize mechanical properties of wire-arc additively manufactured 17-4 PH stainless steel," Additive Manufacturing, vol. 58, 2022.
[37]
R. Li et al., "Nonlinearity in mass spectrometry for quantitative multi-component gas analysis in reaction processes," Analytica Chimica Acta, vol. 1194, pp. 339412, 2022.
[38]
Y. Das et al., "Quantitative Nanostructure and Hardness Evolution in Duplex Stainless Steels : Under Real Low-Temperature Service Conditions," Metallurgical and Materials Transactions. A, vol. 53, no. 2, pp. 723-735, 2022.
[39]
Y. Yang et al., "Revealing the interdependence of microstructure evolution, micromechanics and macroscopic mechanical behavior of multi-phase medium Mn steels," Materials Science & Engineering : A, vol. 839, 2022.
[40]
M. Rolinska, F. Gustavsson and P. Hedström, "Revisiting the applications of the extraction replica sample preparation technique for analysis of precipitates in engineering alloys," Materials Characterization, vol. 189, pp. 111978, 2022.
[41]
A. Kermanpur et al., "Simulation and experimental analysis of nanoscale precipitation during ageing treatment of laser powder-bed fusion fabricated IN718 Ni-based superalloy," Materials Characterization, vol. 191, 2022.
[42]
J. Liu et al., "Small-angle neutron scattering study on phase separation in a super duplex stainless steel at 300°C-Comparing hot-rolled and TIG welded material," Materials Characterization, vol. 190, pp. 112044, 2022.
[43]
T. Zhou et al., "Cu precipitation-me diate d formation of reverted austenite during ageing of a 15-5 PH stainless steel," Scripta Materialia, vol. 202, 2021.
[44]
B. Neding et al., "Formation of Dislocations and Stacking Faults in Embedded Individual Grains during In Situ Tensile Loading of an Austenitic Stainless Steel," Materials, vol. 14, no. 20, 2021.
[45]
T. Chang et al., "High-Resolution Microscopical Studies of Contact Killing Mechanisms on Copper-Based Surfaces," ACS Applied Materials and Interfaces, vol. 13, no. 41, pp. 49402-49413, 2021.
[46]
B. Neding et al., "In Situ Bulk Observations and Ab Initio Calculations Revealing the Temperature Dependence of Stacking Fault Energy in Fe–Cr–Ni Alloys," Metallurgical and Materials Transactions. A, vol. 52, no. 12, pp. 5357-5366, 2021.
[47]
S. Lin et al., "In-Situ High-Energy X-ray Diffraction Study of Austenite Decomposition During Rapid Cooling and Isothermal Holding in Two HSLA Steels," Metallurgical and Materials Transactions. A, vol. 52, no. 5, pp. 1812-1825, 2021.
[48]
S. Xiang et al., "Influence of ferritic nitrocarburizing on the high-temperature corrosion-fatigue properties of the Si-Mo-Al cast iron SiMo1000," International Journal of Fatigue, vol. 143, 2021.
[49]
Z. Sheng et al., "Langer–Schwartz–Kampmann–Wagner precipitation simulations : assessment of models and materials design application for Cu precipitation in PH stainless steels," Journal of Materials Science, vol. 56, no. 3, pp. 2650-2671, 2021.
[50]
M. M. Hoseini-Athar et al., "Microstructure and superplasticity of Mg-2Gd-xZn alloys processed by equal channel angular pressing," Materials Science & Engineering : A, vol. 808, 2021.
[51]
T. Zhou et al., "On the role of transmission electron microscopy for precipitation analysis in metallic materials," Critical reviews in solid state and materials sciences, pp. 1-27, 2021.
[52]
A. Dahlström et al., "Precision Thermal Treatments, Atom Probe Characterization, and Modeling to Describe the Fe-Cr Metastable Miscibility Gap," Metallurgical and Materials Transactions. A, vol. 52, no. 4, pp. 1453-1464, 2021.
[53]
W. Mu et al., "Predicting strain-induced martensite in austenitic steels by combining physical modelling and machine learning," Materials & design, vol. 197, 2021.
[54]
A. B. Yildiz et al., "Quantification of nano-scale interface structures to guide mechanistic modelling of WC grain coarsening inhibition in V-doped hard metals," Materials & design, vol. 207, 2021.
[55]
A. Ståhlkrantz et al., "Revealing the Unexpected Two Variant Pairing Shifts Due to Temperature Change in a Single Bainitic Medium Carbon Steel," Metallurgical and Materials Transactions. A, vol. 52, no. 10, pp. 4546-4557, 2021.
[56]
P. B. Revathy Rajan et al., "A transmission electron microscopy study of discontinuous precipitation in the high misfit system (Ti,Zr)C," Materials Today Communications, vol. 25, 2020.
[57]
A. Ståhlkrantz et al., "Effect of Tempering on the Bainitic Microstructure Evolution Correlated with the Hardness in a Low-Alloy Medium-Carbon Steel," Metallurgical and Materials Transactions. A, vol. 51, no. 12, pp. 6470-6481, 2020.
[58]
M. M. Hoseini-Athar et al., "Effect of Zn content on the microstructural stability and grain growth kinetics of fine-grained extruded Mg-Gd-Zn alloys," Journal of Alloys and Compounds, vol. 831, 2020.
[59]
S. Xiang et al., "Influence of graphite morphology on the corrosion-fatigue properties of the ferritic Si-Mo-Al cast iron SiMo1000," International Journal of Fatigue, vol. 140, 2020.
[60]
T. Zhou, J. Lu and P. Hedström, "Mechanical Behavior of Fresh and Tempered Martensite in a CrMoV-Alloyed Steel Explained by Microstructural Evolution and Strength Modeling," Metallurgical and Materials Transactions. A, vol. 51, no. 10, pp. 5077-5087, 2020.
[61]
M. M. Hoseini-Athar et al., "Microstructure, texture, and strain-hardening behavior of extruded Mg-Gd-Zn alloys," Materials Science & Engineering : A, vol. 772, 2020.
[62]
A. Dahlström et al., "Nanostructure in Fe0.65Cr0.35 close to the upper limit of the miscibility gap," Scripta Materialia, vol. 180, pp. 62-65, 2020.
[63]
X. Xu et al., "Nuclear and magnetic small-angle neutron scattering in self-organizing nanostructured Fe1−xCrx alloys," Materials Characterization, vol. 164, 2020.
[64]
Z. Hou et al., "On coarsening of cementite during tempering of martensitic steels," Materials Science and Technology, vol. 36, no. 7, pp. 887-893, 2020.
[65]
T. Zhou et al., "Precipitation of multiple carbides in martensitic CrMoV steels - experimental analysis and exploration of alloying strategy through thermodynamic calculations," Materialia, vol. 9, 2020.
[66]
[67]
M. M. Hoseini-Athar et al., "Tailoring the texture of an extruded Mg sheet through constrained groove pressing for achieving low mechanical anisotropy and high yield strength," Scripta Materialia, vol. 186, pp. 253-258, 2020.
[68]
M. M. Hoseini-Athar et al., "Tailoring the texture of an extruded Mg sheet through constrained groove pressing for achieving low mechanical anisotropy and high yield strength (vol 186, pg 253, 2020)," Scripta Materialia, vol. 188, pp. 92-95, 2020.
[69]
D. Linder et al., "A comparative study of microstructure and magnetic properties of a Ni–Fe cemented carbide : Influence of carbon content," International journal of refractory metals & hard materials, vol. 80, pp. 181-187, 2019.
[70]
Z. Hou et al., "Early stages of cementite precipitation during tempering of 1C-1Cr martensitic steel," Journal of Materials Science, vol. 54, no. 12, pp. 9222-9234, 2019.
[71]
M. M. Hoseini-Athar et al., "Effect of Zn addition on dynamic recrystallization behavior of Mg-2Gd alloy during high-temperature deformation," Journal of Alloys and Compounds, vol. 806, pp. 1200-1206, 2019.
[72]
Z. Hou et al., "Effect of carbon content on the Curie temperature of WC-NiFe cemented carbides," International journal of refractory metals & hard materials, vol. 78, pp. 27-31, 2019.
[73]
Z. Hou et al., "Evaluating magnetic properties of composites from model alloys – Application to alternative binder cemented carbides," Scripta Materialia, vol. 168, pp. 96-99, 2019.
[74]
D. S. Molnár et al., "Experimental study of the γ-surface of austenitic stainless steels," Acta Materialia, vol. 173, pp. 34-43, 2019.
[75]
T. Zhou et al., "Exploring the relationship between the microstructure and strength of fresh and tempered martensite in a maraging stainless steel Fe-15Cr-5Ni," Materials Science & Engineering : A, vol. 745, pp. 420-428, 2019.
[76]
M. Rahaman et al., "Machine Learning to Predict the Martensite Start Temperature in Steels," Metallurgical and Materials Transactions. A, vol. 50A, no. 5, pp. 2081-2091, 2019.
[77]
M. M. Hoseini-Athar et al., "Microstructural evolution and superplastic behavior of a fine-grained Mg-Gd alloy processed by constrained groove pressing," Materials Science & Engineering : A, vol. 754, pp. 390-399, 2019.
[78]
X. Xu et al., "Nanostructure, microstructure and mechanical properties of duplex stainless steels 25Cr-7 Ni and 22Cr-5Ni (wt.%) aged at 325 degrees C," Materials Science & Engineering : A, vol. 754, no. ALGUE A, 1990, JOURNAL OF MATERIALS SCIENCE, V25, P4977, pp. 512-520, 2019.
[79]
A. B. Yildiz et al., "Very-small angle neutron scattering study on grain coarsening inhibition by V-doping of WC-Co composites," Scripta Materialia, vol. 173, pp. 106-109, 2019.
[80]
Y. Tian, A. Forsberg and P. Hedström, "Comparing the deformation-induced martensitic transformation with the athermal martensitic transformation in Fe-Cr-Ni alloys," Journal of Alloys and Compounds, vol. 766, pp. 131-139, 2018.
[81]
K. Yvell et al., "EBSD analysis of surface and bulk microstructure evolution during interrupted tensile testing of a Fe-19Cr-12Ni alloy," Materials Characterization, vol. 141, pp. 8-18, 2018.
[82]
X. Xu et al., "Effect of heat treatment above the miscibility gap on nanostructure formation due to spinodal decomposition in Fe-52.85 at.%Cr," Acta Materialia, vol. 145, pp. 347-358, 2018.
[83]
T. Ma, P. Hedström and J. Odqvist, "Effect of synthesis temperature and aging on the microstructure and hardness of Ti-Zr-C," International journal of refractory metals & hard materials, vol. 73, pp. 99-105, 2018.
[84]
W. Mu et al., "High-Temperature Confocal Laser Scanning Microscopy Studies of Ferrite Formation in Inclusion-Engineered Steels : A Review," JOM : The Member Journal of TMS, vol. 70, no. 10, pp. 2283-2295, 2018.
[85]
Y. Tian et al., "Micromechanics and microstructure evolution during in situ uniaxial tensile loading of TRIP-assisted duplex stainless steels," Materials Science & Engineering : A, vol. 734, pp. 281-290, 2018.
[86]
K. Yvell et al., "Microstructure development in a high-nickel austenitic stainless steel using EBSD during in situ tensile deformation," Materials Characterization, vol. 135, pp. 228-237, 2018.
[87]
Z. Hou et al., "Microstructure evolution during tempering of martensitic Fe-C-Cr alloys at 700 A degrees C," Journal of Materials Science, vol. 53, no. 9, pp. 6939-6950, 2018.
[88]
H. Zhang et al., "Prediction of Influences of Co, Ni, and W Elements on Carbide Precipitation Behavior in Fe–C–V–Cr–Mo Based High Speed Steels," Steel Research International, vol. 89, no. 10, 2018.
[89]
T. Zhou et al., "Quantitative electron microscopy and physically based modelling of Cu precipitation in precipitation-hardening martensitic stainless steel 15-5 PH," Materials & design, vol. 143, pp. 141-149, 2018.
[90]
R. Borrajo-Pelaez and P. Hedström, "Recent Developments of Crystallographic Analysis Methods in the Scanning Electron Microscope for Applications in Metallurgy," Critical reviews in solid state and materials sciences, vol. 43, no. 6, pp. 455-474, 2018.
[91]
Y. Tian et al., "Deformation Microstructure and Deformation-Induced Martensite in Austenitic Fe-Cr-Ni Alloys Depending on Stacking Fault Energy," Metallurgical and Materials Transactions. A, vol. 48A, no. 1, pp. 1-7, 2017.
[92]
X. Xu et al., "Effect of cooling rate after solution treatment on subsequent phase separation during aging of Fe-Cr alloys : A small-angle neutron scattering study," Acta Materialia, vol. 134, pp. 221-229, 2017.
[93]
J. Zhou et al., "Effect of solution treatment on spinodal decomposition during aging of an Fe-46.5 at.% Cr alloy," Journal of Materials Science, vol. 52, no. 1, pp. 326-335, 2017.
[94]
T. Ma et al., "Liquid Phase Sintering of (Ti,Zr)C with WC-Co," Materials, vol. 10, no. 1, pp. 57, 2017.
[95]
Y. Tian et al., "Martensite formation during incremental cooling of Fe-Cr-Ni alloys : An in-situ bulk X-ray study of the grain-averaged and single-grain behavior," Scripta Materialia, vol. 136, pp. 124-127, 2017.
[96]
O. Nosko et al., "Porosity and shape of airborne wear microparticles generated by sliding contact between a low-metallic friction material and a cast iron," Journal of Aerosol Science, vol. 113, pp. 130-140, 2017.
[97]
S. N. Gunasekara et al., "The Experimental Phase Diagram Study of the Binary Polyols System Erythritol-Xylitol," Solar Energy Materials and Solar Cells, vol. 174, pp. 248-262, 2017.
[98]
F. Huyan et al., "A Thermodynamic-Based Model to Predict the Fraction of Martensite in Steels," Metallurgical and Materials Transactions. A, vol. 47A, no. 9, pp. 4404-4410, 2016.
[99]
W. Mu et al., "Ferrite Formation Dynamics and Microstructure Due to Inclusion Engineering in Low-Alloy Steels by Ti2O3 and TiN Addition," Metallurgical and materials transactions. B, process metallurgy and materials processing science, vol. 47, no. 4, pp. 2133-2147, 2016.
[100]
W. Ding, P. Hedström and Y. Li, "Heat treatment, microstructure and mechanical properties of a C-Mn-Al-P hot dip galvanizing TRIP steel," Materials Science & Engineering : A, vol. 674, pp. 151-157, 2016.
[101]
T. Ma et al., "Microstructure evolution during phase separation in Ti-Zr-C," International journal of refractory metals & hard materials, vol. 61, pp. 238-248, 2016.
[102]
Z. Hou et al., "Quantitative modeling and experimental verification of carbide precipitation in a martensitic Fe-0.16 wt%C-4.0 wt%Cr alloy," Calphad, vol. 53, pp. 39-48, 2016.
[103]
X. Xu et al., "Structural Characterization of Phase Separation in Fe-Cr : A Current Comparison of Experimental Methods," Metallurgical and Materials Transactions. A, vol. 47A, no. 12, pp. 5942-5952, 2016.
[104]
J. E. Westraadt et al., "A high-resolution analytical scanning transmission electron microscopy study of the early stages of spinodal decomposition in binary Fe-Cr," Materials Characterization, vol. 109, pp. 216-221, 2015.
[105]
A. M. Tahir et al., "Behaviour of master alloy during sintering of PM steels : redistribution and dimensional variations," Powder Metallurgy, vol. 58, no. 2, pp. 133-141, 2015.
[106]
W. Mu et al., "Combination of in situ microscopy and calorimetry to study austenite decomposition in inclusion engineered steels," Steel Research International, 2015.
[107]
J. Zhou et al., "Direct atom probe tomography observations of concentration fluctuations in Fe-Cr solid solution," Scripta Materialia, vol. 98, pp. 13-15, 2015.
[108]
M. Hörnqvist et al., "Early stages of spinodal decomposition in Fe-Cr resolved by in-situ small-angle neutron scattering," Applied Physics Letters, vol. 106, no. 6, 2015.
[109]
N. Pettersson et al., "Nanostructure evolution and mechanical property changes during aging of a super duplex stainless steel at 300°C," Materials Science & Engineering : A, vol. 647, pp. 241-248, 2015.
[110]
T. Ma et al., "Self-organizing nanostructured lamellar (Ti,Zr)C - A superhard mixed carbide," International journal of refractory metals & hard materials, vol. 51, pp. 25-28, 2015.
[111]
A. M. Tahir et al., "Cu redistribution during sintering of Fe–2Cu and Fe–2Cu–0·5C compacts," Powder Metallurgy, vol. 57, no. 5, pp. 373-379, 2014.
[112]
F. Huyan et al., "Effect of Solute Silicon on the Lattice Parameter of Ferrite in Ductile Irons," ISIJ International, vol. 54, no. 1, pp. 248-250, 2014.
[113]
I. Borgh et al., "Effect of carbon activity and powder particle size on WC grain coarsening during sintering of cemented carbides," International journal of refractory metals & hard materials, vol. 42, pp. 30-35, 2014.
[114]
M. Nabeel, R. Frykholm and P. Hedström, "Influence of alloying elements on Ni distribution in PM steels," Powder Metallurgy, vol. 57, no. 2, pp. 111-118, 2014.
[115]
J. Zhou et al., "Initial clustering - A key factor for phase separation kinetics in Fe-Cr-based alloys," Scripta Materialia, vol. 75, pp. 62-65, 2014.
[116]
Z. Hou et al., "Microstructure of Martensite in Fe-C-Cr and its Implications for Modelling of Carbide Precipitation during Tempering," ISIJ International, vol. 54, no. 11, pp. 2649-2656, 2014.
[117]
I. Borgh et al., "Microstructure, grain size distribution and grain shape in WC-Co alloys sintered at different carbon activities," International Journal of Refractory Metals and Hard Materials, vol. 43, pp. 205-211, 2014.
[118]
I. Borgh et al., "Synthesis and phase separation of (Ti,Zr)C," Acta Materialia, vol. 66, pp. 209-218, 2014.
[119]
A. Stormvinter, P. Hedström and A. Borgenstam, "A Transmission Electron Microscopy Study of Plate Martensite Formation in High-carbon Low Alloy Steels," Journal of Materials Science & Technology, vol. 29, no. 4, pp. 373-379, 2013.
[120]
Q. Liu et al., "Dynamic Precipitation Behavior of Secondary M7C3 Carbides in Ti-alloyed High Chromium Cast Iron," ISIJ International, vol. 53, no. 7, pp. 1237-1244, 2013.
[121]
I. Borgh et al., "On the three-dimensional structure of WC grains in cemented carbides," Acta Materialia, vol. 61, no. 13, pp. 4726-4733, 2013.
[122]
J. Zhou et al., "Quantitative Evaluation of Spinodal Decomposition in Fe-Cr by Atom Probe Tomography and Radial Distribution Function Analysis," Microscopy and Microanalysis, vol. 19, no. 3, pp. 665-675, 2013.
[123]
P. Hedström et al., "The 475 degrees C embrittlement in Fe-20Cr and Fe-20Cr-X (X=Ni, Cu, Mn) alloys studied by mechanical testing and atom probe tomography," Materials Science & Engineering : A, vol. 574, pp. 123-129, 2013.
[124]
P. Hedström et al., "A phase-field and electron microscopy study of phase separation in Fe-Cr," Materials Science & Engineering : A, vol. 534, pp. 552-556, 2012.
[125]
H. K. Yeddu et al., "A phase-field study of the physical concepts of martensitic transformations in steels," Materials Science & Engineering : A, vol. 538, pp. 173-181, 2012.
[126]
J. Zhou et al., "Concurrent phase separation and clustering in the ferrite phase during low temperature stress aging of duplex stainless steel weldments," Acta Materialia, vol. 60, no. 16, pp. 5818-5827, 2012.
[127]
P. Kolmskog et al., "Direct Observation that Bainite can Grow Below M-S," Metallurgical and Materials Transactions. A, vol. 43A, no. 13, pp. 4984-4988, 2012.
[128]
A. Stormvinter et al., "Effect of carbon content on variant pairing of martensite in Fe-C alloys," Acta Materialia, vol. 60, no. 20, pp. 7265-7274, 2012.
[129]
Q. Liu et al., "Effect of heat treatment on microstructure and mechanical properties of Ti-alloyed hypereutectic high chromium cast iron," ISIJ International, vol. 52, no. 12, pp. 2288-2294, 2012.
[130]
M. Thuvander et al., "Observations of copper clustering in a 25Cr-7Ni super duplex stainless steel during low-temperature aging under load," Philosophical Magazine Letters, vol. 92, no. 7, pp. 336-343, 2012.
[131]
W. Xiong et al., "An improved thermodynamic modeling of the Fe-Cr system down to zero kelvin coupled with key experiments," Calphad, vol. 35, no. 3, pp. 355-366, 2011.
[132]
A. Borgenstam et al., "On the Symmetry Among the Diffusional Transformation Products of Austenite," Metallurgical and Materials Transactions. A, vol. 42A, no. 6, pp. 1558-1574, 2011.
[133]
Z. Ning et al., "Quantum rod-sensitized solar cells," ChemSusChem, vol. 4, no. 12, pp. 1741-1744, 2011.
[134]
R. Naraghi, P. Hedström and A. Borgenstam, "Spontaneous and Deformation-Induced Martensite in Austenitic Stainless Steels with Different Stability," STEEL RES INT, vol. 82, no. 4, pp. 337-345, 2011.
[135]
P. Hedström et al., "Load partitioning between single bulk grains in a two-phase duplex stainless steel during tensile loading," Acta Materialia, vol. 58, no. 2, pp. 734-744, 2010.
[136]
P. Hedström et al., "Load Partitioning and Strain-Induced Martensite Formation during Tensile Loading of a Metastable Austenitic Stainless Steel," Metallurgical and Materials Transactions. A, vol. 40A, no. 5, pp. 1039-1048, 2009.
[137]
R. Mangalaraja et al., "Microwave assisted combustion synthesis of nanocrystalline yttria and its powder characteristics," Powder Technology, vol. 191, no. 3, pp. 309-314, 2009.
[138]
P. Hedström et al., "Elastic strain evolution and ε-martensite formation in individual austenite grains during in situ loading of a metastable stainless steel," Materials letters (General ed.), vol. 62, pp. 338-340, 2008.
[139]
A. Knutsson, P. Hedström and M. Odén, "Reverse martensitic transformation and resulting microstructure in a cold rolled metastable austenitic stainless steel," Steel Research International, vol. 79, no. 6, pp. 433-439, 2008.
[140]
J. Ukonsaari et al., "Tribological studies on an eal lubricated bearing bronze - Steel pair under reciprocating sliding conditions," Tribologia, vol. 27, no. 1, pp. 3-18, 2008.
[141]
P. Hedström et al., "Stepwise transformation behavior of the strain-induced martensitic transformation in a metastable stainless steel," Scripta Materialia, vol. 56, pp. 213-216, 2007.
[142]
P. Hedström et al., "Evolution of residual strains in metastable austenitic stainless steels and the accompanying strain induced martensitic transformation," Materials Science Forum, vol. 524-525, pp. 818-826, 2006.
Conference papers
[143]
T. Loaiza et al., "A Study on the Damage Behavior of Hybrid 60 and 52100 Steel during Rolling Contact Fatigue," in Proceedings 1st ASTM Bearing and Transmission Steels Technology Symposium, 2024, pp. 525-540.
[144]
A. Dahlström et al., "An Experimental Assessment of the alpha plus alpha ' Miscibility Gap in Fe-Cr," in TMS 2017 146TH ANNUAL MEETING & EXHIBITION SUPPLEMENTAL PROCEEDINGS, 2017, pp. 711-718.
[145]
Y. Tian, A. Borgenstam and P. Hedström, "A microstructural investigation of athermal and deformation-induced martensite in Fe-Cr-Ni alloys," in MATERIALS TODAY-PROCEEDINGS, 2015, pp. 687-690.
[146]
F. Huyan, P. Hedström and A. Borgenstam, "Modelling of the fraction of martensite in low-alloy steels," in MATERIALS TODAY-PROCEEDINGS, 2015, pp. 561-564.
[147]
Z. Hou et al., "Study of carbide precipitation during tempering of martensite in an Fe-Cr-C alloy," in PTM 2015 - Proceedings of the International Conference on Solid-Solid Phase Transformations in Inorganic Materials 2015, 2015, pp. 685-686.
[148]
A. M. Tahir et al., "Investigation of Cu distribution and porosity in Fe-2Cu and Fe-2Cu-0.5C compacts," in International Powder Metallurgy Congress and Exhibition, Euro PM 2013, 2013.
[149]
J. Odqvist et al., "3D analysis of phase separation in ferritic stainless steels," in Proceedings of the 1st International Conference on 3D Materials Science, 2012, pp. 221-226.
[150]
I. Borgh et al., "Investigation of phase separation in the (TI, ZR)C system," in Advances in Powder Metallurgy and Particulate Materials - 2012, Proceedings of the 2012 International Conference on Powder Metallurgy and Particulate Materials, PowderMet 2012, 2012, pp. 81-810.
[151]
P. Hedström et al., "On the Three-Dimensional Microstructure of Martensite in Carbon Steels," in Proceedings Of The 1st International Conference On 3D Materials Science, 2012, pp. 19-24.
[152]
J. Zhou et al., "A study of duplex stainless steels aged at 325°C under applied tensile load," in 7th European Stainless Steel Conference : Science and Market, Proceedings, 2011.
[153]
A. Stormvinter, P. Hedström and A. Borgenstam, "Investigation of Lath and Plate Martensite in a Carbon Steel," in International Conference on Solid-Solid Phase Transformations in Inorganic Materials, 2011, pp. 61-66.
[154]
M. Terner et al., "Residual stress evolution during decomposition of Ti(1-x)Al (x)N coatings using high-energy x-rays," in RESIDUAL STRESSES VII, 2006, pp. 619-624.
Non-peer reviewed
Chapters in books
[155]
J. Odqvist and P. Hedström, "Ahierarchic modelling approach to phase separation of ferrite in stainless steels," in Stainless Steel: Microstructure, Mechanical Properties and Methods of Application, : Nova Science Publishers, 2015, pp. 107-121.
[156]
P. Hedström and J. Odqvist, "Deformation-induced martensitic transformation in metastable austenitic stainless steels - introduction and current perspectives," in Stainless Steel : Microstructure, Mechanical Properties and Methods of Application, : Nova Science Publishers, 2015, pp. 82-106.
Reports
[157]
T. Zhou et al., "Streamliningin-situ SAXS/WAXS heat treatment experimentsat the PETRA III Swedish Materials Science beamline," Stockholm : Center for X-Rays in Swedish Materials Science, TRITA-ITM-RP, 2024:2, 2024.
[158]
G. Spartacus et al., "Overview of sample enironments for research use at the PETRA III Swedish Materials Science beamline," Stockholm, TRITA-ITM-RP, 2022:3, 2023.
[159]
T. Zhou et al., "Inventory of data reduction and analysis software used in high-energy X-ray research at PETRA III : WAXS, SAXS, GIWAXS, GISAXS, PDF," , TRITA-ITM-RP, 2020:2, 2022.
Other
[160]
T. Loaiza, P. Ölund and P. Hedström, "Microstructure Stability during Rolling Contact Fatigue : A Comparative Study of a Martensitic and a precipitation-strengthened Martensitic Steel," (Manuscript).
[161]
[162]
[163]
A. M. Tahir et al., "Behavior of master alloy during sintering of PM steels : redistributionand dimensional variations," (Manuscript).
[164]
[165]
Y. Tian, A. Borgenstam and P. Hedström, "Comparing the deformation-induced martensitic transformation with the athermal martensitic transformation in Fe-Cr-Ni alloys," (Manuscript).
[166]
A. B. Yildiz et al., "Design, synthesis, structure, and stability of novel multi-principal element (Ti,Zr,Hf,W)C ceramic with a miscibility gap," (Manuscript).
[167]
J. Zhou et al., "Direct atom probe tomography observations of concentration fluctuationsin Fe-Cr solid solution," (Manuscript).
[168]
Z. Hou et al., "Early stages of cementite precipitation during tempering of 1C-1Cr martensitic steel," (Manuscript).
[169]
S. Lin et al., "Effect of Mo addition on bainite formation in steels - A high-energy X-ray diffraction study," (Manuscript).
[170]
[171]
J. Zhou et al., "Effect of homogenization temperatureon subsequent spinodal decompositionduring aging in Fe-46.5Cr alloy," (Manuscript).
[172]
W. Mu et al., "Ferrite Formation Dynamics and Microstructures in Inclusion Engineered Steels with Ti2O3 and TiN Additions," (Manuscript).
[173]
[174]
[175]
P. Kolmskog, P. Hedström and A. Borgenstam, "Kinetic Study of Transformations ofAustenite in a 4.12 mass% Cr 0.88 mass% C Steel," (Manuscript).
[176]
A. B. Yildiz et al., "Manipulating the decomposition kinetics of a mixed carbide through small compositional adjustments," (Manuscript).
[177]
T. Zhou, J. Lu and P. Hedström, "Mechanical behavior of fresh and tempered martensite in a CrMoV-alloyed steel explained by microstructural evolution and model predictions," (Manuscript).
[178]
Y. Tian et al., "Mechanical stability of austenite grains towards martensitic transformation in a TRIP-assisted duplex stainless steel," (Manuscript).
[179]
T. Loaiza et al., "Micromechanical response of dual-hardening martensitic bearing steel before and after rolling contact fatigue," (Manuscript).
[180]
[181]
[182]
X. Xu et al., "Nuclear and magnetic small-angle neutron scattering in self-organizing nanostructured FexCr1-x alloys," (Manuscript).
[183]
T. Ma, P. Hedström and J. Odqvist, "Powder-metallurgical synthesis and aging of (V,Nb)C and (V,Ta)C," (Manuscript).
[184]
[185]
[186]
T. Zhou et al., "Recent developments in transmission electron microscopy based characterization of precipitation in metallic alloys," (Manuscript).
[187]
[188]
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