Your search keyword '"Hyokyung Sung"' showing total 90 results

51. Effect of stabilization annealing on SCC susceptibility of β-annealed Ti-6Al-4V alloy in 0.6 M NaCl solution

Author

Hyokyung Sung, Yongnam Kwon, Soojin Ahn, Jiho Park, Sangshik Kim, and Daeho Jeong

Subjects

Materials science, Aqueous solution, Hydrogen, Annealing (metallurgy), 020502 materials, Alloy, Metals and Alloys, chemistry.chemical_element, 02 engineering and technology, Strain rate, engineering.material, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Corrosion, Cathodic protection, 0205 materials engineering, chemistry, Mechanics of Materials, Materials Chemistry, engineering, Stress corrosion cracking, Composite material, 0210 nano-technology

Abstract

The effect of stabilization annealing on the stress corrosion cracking (SCC) susceptibility of β-annealed Ti-6Al-4V (Ti64) alloy was examined in an aqueous 0.6 M NaCl solution under various applied potentials of +0.1, -0.05 and -0.1 V vs Ecorr, respectively, at a strain rate of 10 -6 s -1. The stabilization annealing substantially improved the resistance to SCC of β-annealed Ti64 alloy in 0.6 M NaCl solution under cathodic applied potentials, while the effect was marginal under an anodic applied potential. It was also noted that the areal fraction between ductile and brittle fracture of β-annealed Ti64 specimens, which were slow strain rate tested in 0.6 M NaCl solution, varied with stabilization annealing and applied potentials. The effect of stabilization annealing on the SCC behavior of β-annealed Ti64 alloy in SCC-causing environment was discussed based on the micrographic and fractographic observation.

Published

2018

52. Metastable δ-ferrite and twinning-induced plasticity on the strain hardening behavior of directed energy deposition-processed 304L austenitic stainless steel

Author

Taehyun Nam, Hoon Sohn, Ikgeun Jeon, Hyoung Seop Kim, Jae Bok Seol, Duu-Jong Lee, Jung Gi Kim, Hyokyung Sung, Jonghyun Jeong, Yukyeong Lee, and Jeong Min Park

Subjects

Austenite, Materials science, Biomedical Engineering, Strain hardening exponent, engineering.material, Plasticity, Microstructure, Industrial and Manufacturing Engineering, Ferrite (iron), engineering, General Materials Science, Composite material, Austenitic stainless steel, Ductility, Crystal twinning, Engineering (miscellaneous)

Abstract

Rapid melting and solidification cycles during laser-based additive manufacturing create non-equilibrium microstructures in stainless steels (SSs) including atomic segregation-mediated ultrafine δ-ferrite, in contrast to coarse δ-ferrite in typical casting-produced SSs. The formation of metastable ultrafine δ-ferrite in additively manufactured SSs generates a new coherent interface in austenitic matrix. However, currently a consensus on how ultrafine δ-ferrite interacts with dislocations is lacking, particularly in directed energy deposition-processed 304L SS. Herein, the role of ultrafine δ-ferrite on the mechanical properties of directed energy deposition-processed 304L SS was investigated by modifying the laser scan speeds of 850 and 1150 mm/min and by performing electron microscopy-based characterization. We find that the ultrafine δ-ferrite maintains coherency with a γ-austenite matrix in the undeformed state and interacts with dislocations during plastic deformation. Additionally, the twin volume fraction depends on the initial grain size of 304L SSs, which results in a 23 MPa (for strength) and 5% (for ductility) mechanical property difference between the 850 (SLOW) and 1150 (FAST) mm/min scan speed conditions. Through the synergetic effects of ultrafine δ-ferrite, deformation-induced twins and twin intersections, the present additively manufactured 304L SS achieves an outstanding ductility that is larger than that of the previous directed energy deposition-processed SSs. This result proves that the ultrafine metastable phase contributes to the prolonged plasticity of the additively manufactured metallic alloys if the metastable phase maintains coherency with the matrix during plastic deformation.

Published

2021

53. Near atomic-scale comparison of passive film on a 17 wt% Cr-added 18 wt% Mn steel with those on typical austenitic stainless steels

Author

Muhammad Ishtiaq, Jung Gi Kim, Hyokyung Sung, Jong Chan Han, Kwang Kyu Ko, Eun Tae Kim, Jae Bok Seol, and Hyo Ju Bae

Subjects

Austenite, chemistry.chemical_classification, Materials science, Base (chemistry), Mechanical Engineering, Metals and Alloys, Atom probe, Condensed Matter Physics, Atomic units, Corrosion, law.invention, Cracking, chemistry, Mechanics of Materials, law, Scanning transmission electron microscopy, General Materials Science, Composite material, Wurtzite crystal structure

Abstract

The passive films on typical stainless steels (SS) and on a newly developed high-Cr (17 wt%)-added 18 wt%-Mn steel (HCr-HMnS) were compared by Cs-corrected scanning transmission electron microscopy and atom probe tomography. Although the passive films of all samples having similar Cr contents had the same thickness, unprecedented hexagonal wurtzite MnO inside the passive film of HCr-HMnS specimen was susceptible to corrosion cracking; this was not observed in the SS samples. This MnO caused crack formation during potentiodynamic polarization test, suggesting that reducing the harmful MnO by adding Mo and Ni facilitates the development of high-Mn base SS materials . Furthermore, higher MoO2 composition of the passive films on 316 type austenitic SS than 304 type series might would result in primarily the improved pitting resistance.

Published

2021

54. Effect of Interdendritic Precipitations on the Mechanical Properties of GBF or EMS Processed Al-Zn-Mg-Cu Alloys

Author

Hyokyung Sung, Hyungrae Kim, Im Doo Jung, Kwangjun Euh, Jung Gi Kim, Sangeun Park, N.S. Reddy, Jae Bok Seol, and Saif Haider Kayani

Subjects

Equiaxed crystals, Crystallography, Materials science, Tensile fracture, EMS process, General Chemical Engineering, Al-Zn-Mg-Cu alloy, Condensed Matter Physics, GBF process, Casting, law.invention, Inorganic Chemistry, Electromagnetic stirring, QD901-999, Transmission electron microscopy, law, precipitates, General Materials Science, Composite material, Filtration, Electron backscatter diffraction

Abstract

The effects of nanoprecipitations on the mechanical properties of Al-Zn-Mg-Cu alloys after GBF (gas bubbling filtration) and EMS (electromagnetic stirring) casting were investigated. Dendritic cell structures were formed after GBF processing, while globular dendritic structures were nucleated after EMS processing. Equiaxed cell sizes were smaller in the EMS-processed specimens compared to the GBF-processed specimens, confirmed by EBSD (electron backscatter diffraction) analysis. Nanoprecipitations of η′ phases inside of dendrites were observed by TEM (transmission electron microscope), and other Fe-bearing compounds were located in the dendritic boundaries. The yield strength of the T4 and T6 heat-treated specimens was close to 400 MPa and 500 MPa, respectively. Fractographic analysis was performed to investigate the effect of precipitations on tensile fracture.

Published

2021

55. Hydrogen-induced ordering on the deformation mechanism of the as-cast high-Mn steel

Author

Jung Gi Kim, Jungsub Lee, Jae Bok Seol, Hyokyung Sung, Donghwa Bae, and Jonghyun Jeong

Subjects

Mechanical property, Materials science, Hydrogen, Mechanical Engineering, chemistry.chemical_element, Slip (materials science), Strain hardening exponent, Physics::Classical Physics, Condensed Matter Physics, Planarity testing, chemistry, Deformation mechanism, Mechanics of Materials, General Materials Science, Physics::Atomic Physics, Composite material, Dislocation, Material properties

Abstract

Diffused hydrogen atoms in high-strength steels induce both cohesive energy drops and dislocation mobility enhancement, which usually degrade the mechanical properties of materials. However, the enhanced dislocation mobility could also increase the slip planarity, which enhances the mechanical properties of materials. In this study, effects of hydrogen charging on the mechanical properties of as-cast high-Mn steels were investigated. Hydrogen charging in the high-Mn steel promotes slip planarity with short-range ordering, which results in a large planar slip band fraction and strain hardening enhancement of the hydrogen-charged sample. This shows that hydrogen-induced ordering can be related to both deformation mechanism and mechanical property of hydrogen charged high-Mn steels.

Published

2021

56. Effects of cooling rate and stabilization annealing on fatigue behavior of β-processed Ti-6Al-4V alloys

Author

Yongnam Kwon, Hyokyung Sung, Dong Jun Lee, Daeho Jeong, Wongyu Seo, and Sangshik Kim

Subjects

Air cooling, Materials science, Annealing (metallurgy), 020502 materials, Metallurgy, Metals and Alloys, Nucleation, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, Cooling rate, 0205 materials engineering, Mechanics of Materials, Residual stress, Ultimate tensile strength, Solid mechanics, Materials Chemistry, 0210 nano-technology

Abstract

The effects of stabilization annealing and cooling rate on high cycle fatigue (HCF) and fatigue crack propagation (FCP) behaviors of β-processed Ti64 alloys were examined. After β-process heating above β transus, two different cooling rates of air cooling (β-annealing) and water quenching (β-quenching) were utilized. Selected specimens were then underwent stabilization annealing. The tensile tests, HCF and FCP tests on conducted on the β-processed Ti64 specimens with and without stabilization annealing. No notable microstructural and mechanical changes with stabilization annealing was observed for the β-annealed Ti64 alloys. However, significant effect of stabilization annealing was found on the FCP behavior of β-quenched Ti64 alloys, which appeared to be related to the built-up of residual stress after quenching. The mechanical behavior of β-processed Ti64 alloys with and with stabilization annealing was discussed based on the micrographic examination, including crack growth path and crack nucleation site, and fractographic analysis.

Published

2017

57. Effects of C and Si on strain aging of strain-based API X60 pipeline steels

Author

Byeong-Joo Lee, Hyokyung Sung, Young-Woon Kim, Sunghak Lee, Seung-Pyo Hong, Jang Yong Yoo, Sang Yong Shin, Byoungchul Hwang, and Dong Ho Lee

Subjects

Austenite, Materials science, 020502 materials, Metallurgy, technology, industry, and agriculture, Metals and Alloys, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, C content, Acicular ferrite, 0205 materials engineering, Mechanics of Materials, Ferrite (iron), Volume fraction, Ultimate tensile strength, Materials Chemistry, Elongation, 0210 nano-technology, Dynamic strain aging

Abstract

Four types of strain-based API X60 pipeline steels were fabricated by varying the C and Si contents, and the effects of C and Si on strain aging were investigated. The 0.05 wt% C steels consisted mainly of polygonal ferrite (PF), whereas the 0.08 wt% C steels consisted of acicular ferrite (AF). The volume fraction of AF increased with increasing C content because C is an austenite stabilizer element. The volume fractions of bainitic ferrite (BF) of the 0.15 wt% Si steels were higher than those of the 0.25 wt% Si steels, whereas the volume fractions of the secondary phases were lower. From the tensile properties before and after the aging process of the strainbased API X60 pipeline steels, the yield strength increased and the uniform and total elongation decreased, which is the strain aging effect. The strain aging effect in the strain-based API X60 pipeline steels was minimized when the volume fraction of AF was increased and secondary phases were distributed uniformly. On the other hand, an excessively high C content formed fine precipitates, and the strain aging effect occurred because of the interactions among dislocations and fine precipitates.

Published

2017

58. Tensile and high cycle fatigue behaviors of high-Mn steels at 298 and 110 K

Author

Sangshik Kim, Hyokyung Sung, Daeho Jeong, and Wongyu Seo

Subjects

Austenite, Materials science, 020502 materials, Mechanical Engineering, Metallurgy, Twip, 02 engineering and technology, Work hardening, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0205 materials engineering, Deformation mechanism, Mechanics of Materials, Ultimate tensile strength, General Materials Science, Deformation (engineering), 0210 nano-technology, Tensile testing, Electron backscatter diffraction

Abstract

Tensile and high cycle fatigue behaviors of high-Mn austenitic steels, including 25Mn, 25Mn0.2Al, 25Mn0.5Cu, 24Mn4Cr, 22Mn3Cr and 16Mn2Al specimens, were investigated at 298 and 110 K. Depending on the alloying elements, tensile ductility of high-Mn steels either increased or decreased with decreasing temperature from 298 to 110 K. Reasonable correlation between the tendency for martensitic tranformation, the critical twinning stress and the percent change in tensile elongation suggested that tensile deformation of high-Mn steels was strongly influenced by SFE determining TRIP and TWIP effects. Tensile strength was the most important parameter in determining the resistance to high cycle fatigue of high-Mn steels with an exceptional work hardening capability at room and cryogenic temperatures. The fatigue crack nucleation mechanism in high-Mn steels did not vary with decreasing tempertature, except Cr-added specimens with grain boundary cracking at 298 K and slip band cracking at 110 K. The EBSD (electron backscatter diffraction) analyses suggested that the deformation mechanism under fatigue loading was significantly different from tensile deformation which could be affected by TRIP and TWIP effects.

Published

2017

59. Modeling and optimization of chlorophenol rejection for spiral wound reverse osmosis membrane modules

Author

V. Sivanantham, Moon Kyoung – Seok, V. Sangeetha, Kwon Jun Hyeong, N.S. Reddy, Hyokyung Sung, Preetham Pareddy, P.L. Narayana, and Kim Hong In

Subjects

Osmosis, Environmental Engineering, Materials science, Spiral wound, Health, Toxicology and Mutagenesis, Computer Science::Neural and Evolutionary Computation, 0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Water Purification, chemistry.chemical_compound, Environmental Chemistry, Reverse osmosis, Process engineering, 0105 earth and related environmental sciences, Chlorophenol, Artificial neural network, business.industry, Public Health, Environmental and Occupational Health, Membranes, Artificial, General Medicine, General Chemistry, Pollution, 020801 environmental engineering, Feed temperature, Volumetric flow rate, chemistry, business, Feed pressure, Filtration, Chlorophenols

Abstract

This study shows an artificial neural network (ANN) model of chlorophenol rejection from aqueous solutions and predicting the performance of spiral wound reverse osmosis (SWRO) modules. This type of rejection shows complex non-linear dependencies on feed pressure, feed temperature, concentration, and feed flow rate. It provides a demanding test of the application of ANN model analysis to SWRO modules. The predictions are compared with experimental data obtained with SWRO modules. The overall agreement between the experimental and ANN model predicted was almost 99.9% accuracy for the chlorophenol rejection. The ANN model approach has the advantage of understanding the complex chlorophenol rejection phenomena as a function of SWRO process parameters.

Published

2021

60. Mechanical property enhancement in gradient structured aluminum alloy by ultrasonic nanocrystalline surface modification

Author

Hyokyung Sung, Hyoung Seop Kim, Auezhan Amanov, Jungsub Lee, Jae Bok Seol, Hae Don Park, Juhee Oh, Minseok Gwak, Sujung Son, and Jung Gi Kim

Subjects

010302 applied physics, Materials science, Mechanical Engineering, Alloy, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Nanocrystalline material, Grain size, Mechanics of Materials, 0103 physical sciences, engineering, Shear stress, Hardening (metallurgy), Surface modification, General Materials Science, Composite material, Deformation (engineering), 0210 nano-technology, Ductility

Abstract

The large strength difference between hard and soft components in heterogeneous structured materials leads to the evolution of high back-stress hardening, which increases the strength and ductility of materials simultaneously. Moreover, the combination of high shear strain and elevated temperature allows an increase in the strength of low-melting temperature metallic alloys by grain refinement, solute migration, and clustering. In this study, to design a new heterogeneous microstructure in the aluminum alloy, both room temperature (RT) and high-temperature (HT) ultrasonic nanocrystalline surface modification (UNSM) were conducted, and their mechanical properties and microstructural evolutions were investigated. The large shear strain from the UNSM treatment reduces the grain size at the sample surface and creates a gradient structure. The combination of shear strain and elevated temperature during UNSM treatment induces solute migration at a certain depth of the specimens, resulting in the nano-sized Mg-rich particles at the surface region. Both grain refinement and precipitation at the surface region of the HT sample provide strong back-stress hardening in the early stages of deformation that enhances the strength and ductility of materials. Therefore, a high shear strain and control of processing temperature allow the design of a unique heterogeneous microstructure in low-melting temperature metallic alloys, which is a good strategy for enhancing the mechanical properties of sheet or thin metallic products.

Published

2021

61. Outstanding mechanical properties of ultrafine-grained Al7075 alloys by high-pressure torsion

Author

Hyoung Seop Kim, Jungsub Lee, Hyesu Ha, Hyogeon Kim, Jae Bok Seol, Sujung Son, Jung Gi Kim, and Hyokyung Sung

Subjects

Materials science, Mechanical Engineering, Alloy, technology, industry, and agriculture, Intermetallic, engineering.material, Condensed Matter Physics, Nanocrystalline material, Brittleness, Precipitation hardening, Mechanics of Materials, engineering, General Materials Science, Deformation (engineering), Dislocation, Composite material, Ductility

Abstract

High frictional die and continuous rotation during high-pressure torsion provide not only a large shear strain but also a large amount of frictional heat that facilitates the generation of complex microstructural changes, including grain refinement, dynamic recovery, and solute migration. Since metallic alloys with low melting temperatures are sensitive to heat energy, the mechanical properties and microstructural evolution of high-pressure torsion-processed aluminum 7075 alloys are investigated in this study. The large shear strain resulting from high-pressure torsion induces both grain refinement and dislocation cell formation, leading to strength enhancement and ductility degradation of the alloy. The deformation and frictional heat become a driving force for solute migration, including brittle intermetallic compound dissolution and nano-sized precipitation generation in the matrix. These solute migration activities contribute toward enhancing both the strength and ductility by inducing precipitation hardening and dissolution of the brittle phase simultaneously. Consequently, both the strength and ductility of the high-pressure torsion-processed aluminum 7075 alloy become larger than that of the initial state. This result shows that the microstructural changes of the severe plastic deformation-processed low-melting-temperature metallic alloys induce a significant mechanical property enhancement of nanocrystalline materials.

Published

2021

62. Reverse effect of hot isostatic pressing on high-speed selective laser melted Ti–6Al–4V alloy

Author

Hyokyung Sung, Jae Bok Seol, Seung Ki Moon, Eun Hyeok Seo, Jungsub Lee, Im Doo Jung, Jung Gi Kim, and Hyunjong Ha

Subjects

0209 industrial biotechnology, Materials science, Mechanical Engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Laser, law.invention, 020901 industrial engineering & automation, Mechanics of Materials, Hot isostatic pressing, law, Martensite, Ultimate tensile strength, Fracture (geology), Surface roughness, General Materials Science, Selective laser melting, Composite material, 0210 nano-technology, Porosity

Abstract

Despite recent progress in achieving high mechanical properties of 3D printed metal products, the low productivity still remains a major limitation for their cost-effective feasibility in practical applications. To achieve high-speed printing with affordable mechanical properties, we increased the scanning speed of selective laser melting process with Ti–6Al–4V up to 1800 mm/s and applied a hot isostatic pressing (HIP) process to compensate for the porosity. In these high-speed printed specimens, the HIP process led to a microstructural change from αʹ-lath martensite to a Widmanstӓtten α-lamellar structure, which deteriorated their tensile properties due to the segregation of β-stabilizing atoms and caused inter-lamellar fracture. The deterioration phenomenon of high-speed printed Ti–6Al–4V specimens after the HIP process was found to be critically affected by the surface roughness of as-built state, which can be efficiently controlled with a build angle set-up.

Published

2021

63. Analysis of damage-tolerance of TRIP-assisted V10Cr10Fe45Co30Ni5 high-entropy alloy at room and cryogenic temperatures

Author

Dae Woong Kim, Sunghak Lee, Junha Yang, Yong Hee Jo, Donghwa Lee, Hyokyung Sung, Woojin An, Seok Su Sohn, Hyoung Seop Kim, and Kyung-Yeon Doh

Subjects

Toughness, Materials science, Mechanical Engineering, Metals and Alloys, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Brittleness, Fracture toughness, Mechanics of Materials, Stacking-fault energy, Martensite, Ultimate tensile strength, Materials Chemistry, Composite material, 0210 nano-technology, Ductility, Damage tolerance

Abstract

A single-phase face-centered-cubic (FCC) high- or medium-entropy alloys (HEAs or MEAs) have attracted great attentions due to their novel damage-tolerance properties (strength, ductility, and fracture toughness) by generating nano-twins at cryogenic temperature. The fracture toughness assessment is essential for evaluating the reliability of high-performance materials for cryogenic applications; however, fracture studies on single-phase FCC HEAs showing transformation-induced plasticity (TRIP) have been hardly conducted. In this study, thus, damage-tolerance mechanisms of a V10Cr10Fe45Co30Ni5 HEA showing the FCC to body-centered-cubic (BCC) TRIP were investigated at room and cryogenic temperatures. At room temperature (298 K), the alloy shows the tensile strength of 731 MPa, elongation of 40%, and fracture toughness (KJIc) of 230 MPa m1/2. At cryogenic temperature (77 K), the strength and elongation improve to 1.2 GPa and 66%, respectively, while the KJIc remains almost constant at 237 MPa m1/2. Dislocation-mediated plasticity prevails at 298 K; however, the TRIP from FCC to BCC occurs at 77 K. Deformation and fracture mechanisms are analyzed by stacking fault energies and differences in Gibbs free energies between phases calculated by ab-initio methods, and are compared to those of CrMnFeCoNi, CrCoNi, Fe50Mn30Co10Cr10, and V10Cr10Fe45Co20Ni15 alloys. Despite the presence of a considerable amount of BCC which is intrinsically brittle at low temperature, the transformed BCC martensite shows ductile fracture after the fracture toughness test even in cryogenic environments. These results demonstrate that the FCC to BCC TRIP can be an attractive route in a field of HEA design to overcome the strength and toughness trade-off at cryogenic temperature.

Published

2020

64. Near-threshold fatigue crack propagation behavior of austenitic high-Mn steels

Author

Hyokyung Sung, Sangshik Kim, Wongyu Seo, and Daeho Jeong

Subjects

Austenite, Materials science, 020502 materials, Mechanical Engineering, Twip, Metallurgy, 02 engineering and technology, Slip (materials science), Plasticity, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Grain size, 0205 materials engineering, Mechanics of Materials, Stacking-fault energy, Ultimate tensile strength, General Materials Science, 0210 nano-technology, Crystal twinning

Abstract

High-Mn austenitic steels utilizing TWIP (twinning induced plasticity) effect have excellent combination of tensile strength and ductility. The near-threshold fatigue crack propagation (FCP) behavior, as represented by the ΔK th value, of high-Mn steels was examined with the emphasis on the effect of stacking fault energy (SFE), grain size, twinning and tensile properties. Even though no predominant parameter determining the near-threshold FCP behavior of high-Mn steels was found, the SFE showed the most reasonable correlation to the ΔK th values among the variables examined. It was also suggested that the slip reversibility as determined by SFE could not solely explain the near-threshold FCP behavior of high-Mn steels. The presence of twin boundaries appeared to be not beneficial in improving the resistance to FCP of high-Mn steels in low ΔK regime. The near-threshold FCP characteristics of high-Mn austenitic steels were discussed and correlated with the well-known parameters presumably affecting FCP.

Published

2016

65. S-N fatigue behavior of Fe25Mn steel and its weld at 298 and 110 K

Author

Sangshik Kim, Hyokyung Sung, Daeho Jeong, Jongseop Lee, and Taedong Park

Subjects

Austenite, Materials science, 020502 materials, fungi, Metallurgy, technology, industry, and agriculture, Metals and Alloys, 02 engineering and technology, Welding, Plasticity, 021001 nanoscience & nanotechnology, Condensed Matter Physics, law.invention, 0205 materials engineering, Mechanics of Materials, law, Stacking-fault energy, Ultimate tensile strength, Materials Chemistry, 0210 nano-technology, Crystal twinning, Joint (geology), Electron backscatter diffraction

Abstract

The S-N fatigue behavior of newly developed Fe25Mn steel, including base metal and butt-welded joint, was investigated at 298 and 110 K, and the results were compared to those of previously reported Fe16Mn2Al and STS304L steels. Fe25Mn steel has quite promising fatigue performance at 298 K and even at 110 K, showing comparable resistance to fatigue to STS304L. The S-N fatigue behavior of Fe25Mn steel was dependent on tensile strength at 298 and 110 K, the trend of which well agreed to that of other austenitic steels. The electron backscatter diffraction and micrographic analyses suggested that transformation induced plasticity and twinning induced plasticity effects did not occur in Fe25Mn steel under fatigue loading at room and cryogenic temperatures. The butt-welded Fe25Mn/Fe25Mn and Fe25Mn/STS304L specimens also showed a satisfactory fatigue behavior which was even comparable to that of STS304L/STS304L specimen at 110 K. The S-N fatigue behavior of Fe25Mn steel and its welds was discussed based on the fractographic and microscopic observations.

Published

2016

66. Fatigue crack propagation behavior of Fe25Mn and Fe16Mn2Al steels at room and cryogenic temperatures

Author

Sangshik Kim, Jongseop Lee, Hyokyung Sung, Taedong Park, and Daeho Jeong

Subjects

Austenite, Materials science, 020502 materials, Effective stress, Metallurgy, Metals and Alloys, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Grain size, Fatigue crack propagation, Cracking, 0205 materials engineering, Mechanics of Materials, Stacking-fault energy, Solid mechanics, Materials Chemistry, Grain boundary, 0210 nano-technology

Abstract

The fatigue crack propagation (FCP) behavior of Fe25Mn and Fe16Mn2Al austenitic steels was investigated at 298 and 110 K, and the results were compared with the reported results of Fe24Mn2Cr steel. It was found that the FCP behavior of high-Mn, austenitic steels was largely influenced by the stacking fault energy (SFE) and the grain size. The resistance to FCP of high-Mn steels in this study was enhanced in the near-threshold ΔK regime with decreasing temperature from 298 to 110 K. The improvement for the Fe25Mn and the Fe16Mn2Al specimen was, however, marginal as compared to that of the Fe24Mn2Cr specimen. Other than the change in SFE, the secondary cracking at cryogenic temperature appeared to affect the FCP behavior of high-Mn steels, since the secondary cracks perpendicular to the crack propagating direction could reduce the effective stress intensity factor, decreasing the FCP rates. Sufficiently high stress concentration at grain boundary tended to occur at low temperature for relatively large grain sized Fe24Mn2Cr specimen and cause the secondary cracking, but not for the Fe25Mn and the Fe16Mn2Al specimen.

Published

2016

67. Effect of superplastic forming exposure on tensile and S-N fatigue behavior of Ti64 alloy

Author

Hyokyung Sung, Yongnam Kwon, Sangshik Kim, Semi Hyun, and Daeho Jeong

Subjects

Materials science, 020502 materials, Metallurgy, Alloy, technology, industry, and agriculture, Metals and Alloys, Superplasticity, 02 engineering and technology, engineering.material, equipment and supplies, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Stress (mechanics), 0205 materials engineering, Mechanics of Materials, Ultimate tensile strength, Solid mechanics, Metallic materials, Materials Chemistry, Fracture (geology), engineering, Vacuum chamber, Composite material, 0210 nano-technology

Abstract

The effect of superplastic forming (SPF) on tensile and S (stress)-N (number of cycles to failure) fatigue properties of Ti64 alloy was examined at 298 and 473 K. For simulating the superplastic forming exposure, millannealed Ti64 alloy sheet was heated in a vacuum chamber with a pre-determined temperature profile. For some as-exposed specimens, the α-case formed on the surface during expousre was mechanically removed to understand the effect of α-case on the mechanical properties of Ti64 alloy. It was found that the presence of α-case significantly affected the tensile and the fatigue properties of Ti64 alloy at 298 and 473 K by providing an easy initiation site for both tensile and fatigue fracture. The microstructural change during the SPF exposure was marginal in affecting the S-N fatigue properties of Ti64 alloy. Different testing temperature of 298 and 473 K affected the S-N fatigue behavior of as-received and as-exposed (α-case removed) Ti64 specimens, but not that of as-exposed specimen.

Published

2016

68. Correlation Between Microstructures and Tensile Properties of Strain-Based API X60 Pipeline Steels

Author

Hyoung Seop Kim, Sunghak Lee, Yunjo Ro, Chang Sun Lee, Sang Yong Shin, Dong Ho Lee, Byoungchul Hwang, and Hyokyung Sung

Subjects

010302 applied physics, Materials science, Metallurgy, Metals and Alloys, 02 engineering and technology, Strain hardening exponent, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, 01 natural sciences, Acicular ferrite, Volume (thermodynamics), Mechanics of Materials, Ferrite (iron), 0103 physical sciences, Ultimate tensile strength, Volume fraction, Elongation, 0210 nano-technology

Abstract

The correlation between the microstructures and tensile properties of strain-based American Petroleum Institute (API) X60 pipeline steels was investigated. Eight types of strain-based API X60 pipeline steels were fabricated by varying the chemical compositions, such as C, Ni, Cr, and Mo, and the finish cooling temperatures, such as single-phase and dual-phase regions. In the 4N and 5C steels, the volume fractions of bainitic ferrite (BF) and the secondary phases increased with the increasing C and adding Cr instead of Ni. In the 5C and 6NC steels, the volume fractions of acicular ferrite (AF) and BF decreased with increasing C and adding Ni, whereas the volume fractions of polygonal ferrite (PF) and the secondary phases increased. In the 6NC and 6NM steels, the volume fraction of BF was increased by adding Mo instead of Cr, whereas the volume fractions of PF and the secondary phases decreased. In the steels rolled in the single-phase region, the volume fraction of polygonal ferrite ranged from 40 to 60 pct and the volume fraction of AF ranged from 20 to 40 pct. In the steels rolled in the dual-phase region, however, the volume fraction of PF was more than 70 pct and the volume fraction of AF was below 20 pct. The strength of the steels with a high volume fraction of AF was higher than those of the steels with a high volume fraction of PF, whereas the yield point elongation and the strain hardening exponent were opposite. The uniform elongation after the thermal aging process decreased with increasing volume fraction of PF, whereas the uniform elongation increased with increasing volume fraction of AF. The strain hardening exponent increased with increasing volume fraction of PF, but decreased with increasing volume fraction of AF and effective grain size.

Published

2016

69. Artificial intelligence for the prediction of tensile properties by using microstructural parameters in high strength steels

Author

Moobum Kim, Seung Ki Moon, Min Sik Lee, Da Seul Shin, Seong Jin Park, Doohee Kim, N.S. Reddy, Kyung Tae Kim, Hye Jin Son, Hyokyung Sung, Sangshik Kim, Jungsub Lee, Im Doo Jung, and Ji-Hun Yu

Subjects

010302 applied physics, Yield (engineering), Materials science, Artificial neural network, Bainite, business.industry, 02 engineering and technology, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Acicular ferrite, Ferrite (iron), Martensite, Volume fraction, 0103 physical sciences, Ultimate tensile strength, General Materials Science, Artificial intelligence, 0210 nano-technology, business

Abstract

Artificial intelligence is widely employed in metallurgy for its ability to solve complex phenomena, which are associated with the learning process of previously obtained experimental data. Although numerous physical modeling techniques have been implemented for the prediction of mechanical strength using equations, several empirical efforts are necessitated to evaluate specific constants for different models. To address this issue, numerous recent studies have employed artificial neural networks for the prediction of mechanical properties based on the material composition and process conditions; however, majority of these works have been limited applications due to the extensive number of input parameter combinations of chemical compositions. Microstructure is a good feature to understand mechanical properties because it incorporates the effects of material composition and process conditions. The complex combination of material composition and process parameters determines the microstructure of steel. In this study, the information on microstructural volume fraction is utilized for the prediction of tensile strength, yield strength, and yield ratio via artificial neural networking. Various combinations of PF (polygonal ferrite), AF (acicular ferrite), GB (granular bainite), BF (bainitic ferrite), and M (martensite) are investigated for the prediction of yield strength, ultimate tensile strength, and yield of high strength steel via back-propagation linear regression and neural network based algorithm. The effects of each microstructure on the three mechanical properties were successfully predicted by employing back-propagation linear regression. A deep learning algorithm with hyper-parameter tuning and cross-validation enabled high accuracy in predicting experimental data with mean absolute percentage errors of 6.59% and 10.78% for the validation and test sets, respectively. These studies can open a new avenue for applying the microstructural design effects to find optimum yield strength, tensile strength, and yield ratio of high strength steel.

Published

2020

70. Embedding sensors using selective laser melting for self-cognitive metal parts

Author

Hyokyung Sung, Seok Woo Lee, Jungsub Lee, Jungho Choe, Moobum Kim, Ki-bong Kim, Sangsun Yang, Im Doo Jung, Min Sik Lee, Jaecheol Yun, Hye Jin Son, Ji-Hun Yu, Kyung Tae Kim, and Seung Ki Moon

Subjects

0209 industrial biotechnology, Materials science, Turbine blade, Laser scanning, business.industry, Biomedical Engineering, Process (computing), 02 engineering and technology, Integrated circuit, 021001 nanoscience & nanotechnology, Laser, Industrial and Manufacturing Engineering, law.invention, Printed circuit board, 020901 industrial engineering & automation, law, Hardware_INTEGRATEDCIRCUITS, Optoelectronics, General Materials Science, Selective laser melting, 0210 nano-technology, business, Inconel, Engineering (miscellaneous)

Abstract

We devised a novel method to embed sensors or integrated circuit (IC) chips into metal components by using a selective laser melting (SLM) process. The concept of a protective layer is introduced to fabricate all parts without damaging the sensors during the laser scanning process. The operation of sensors in the parts is analyzed from a computational analysis on the thermal influence of laser heat. The fabricated metal parts show continuous microstructures including grains and phases between the base part and the new part formed after embedding the sensor despite the intermittent SLM process. The embedded sensor operates properly when compared to bare sensors. Plastic circuit board-based IC components were embedded into an Inconel 718C turbine blade, which accurately distinguished three-dimensional vibration along the X, Y, and Z axes. Our results imply that the proposed process can open new avenues for SLM technology to realize metal components with a self-cognitive ability using integrated sensors.

Published

2020

71. Effects of Finish Cooling Temperature on Tensile Properties After Thermal Aging of Strain-Based API X60 Linepipe Steels

Author

Yunjo Ro, Dong Ho Lee, Sang Yong Shin, Byoungchul Hwang, Hyokyung Sung, Chang Sun Lee, and Sunghak Lee

Subjects

Cottrell atmosphere, Materials science, Mechanics of Materials, Ferrite (iron), Martensite, Ultimate tensile strength, Volume fraction, Metallurgy, Metals and Alloys, Strain hardening exponent, Condensed Matter Physics, Microstructure, Acicular ferrite

Abstract

Two types of strain-based American Petroleum Institute (API) X60 linepipe steels were fabricated at two finish cooling temperatures, 673 K and 723 K (400 °C and 450 °C), and the effects of the finish cooling temperatures on the tensile properties after thermal aging were investigated. The strain-based API X60 linepipe steels consisted mainly of polygonal ferrite (PF) or quasi-polygonal ferrite and the volume fraction of acicular ferrite increased with the increasing finish cooling temperature. In contrast, the volume fractions of bainitic ferrite (BF) and secondary phases decreased. The tensile properties before and after thermal aging at 473 K and 523 K (200 °C and 250 °C) were measured. The yield strength, ultimate tensile strength, and yield ratio increased with the increasing thermal aging temperature. The strain hardening rate in the steel fabricated at the higher finish cooling temperature decreased rapidly after thermal aging, probably due to the Cottrell atmosphere, whereas the strain hardening rate in the steel fabricated at the lower finish cooling temperature changed slightly after thermal aging. The uniform elongation and total elongation decreased with increasing thermal aging temperature, probably due to the interactions between carbon atoms and dislocations. The uniform elongation decreased rapidly with the decreasing volume fractions of BF and martensite and secondary phases. The yield ratio increased with the increasing thermal aging temperature, whereas the strain hardening exponent decreased. The strain hardening exponent of PL steel decreased rapidly after thermal aging because of the large number of mobile dislocations between PF and BF or martensite or secondary phases.

Published

2015

72. Micromechanics of plastic deformation and phase transformation in a three-phase TRIP-assisted advanced high strength steel: Experiments and modeling

Author

Allan F. Bower, Sharvan Kumar, Hassan Ghassemi-Armaki, Hyokyung Sung, Peng Chen, and Ankit Srivastava

Subjects

Austenite, Materials science, Bainite, Mechanical Engineering, Metallurgy, Micromechanics, Strain hardening exponent, Flow stress, Condensed Matter Physics, Mechanics of Materials, Ferrite (iron), Martensite, Composite material, Deformation (engineering)

Abstract

The micromechanics of plastic deformation and phase transformation in a three-phase advanced high strength steel are analyzed both experimentally and by microstructure-based simulations. The steel examined is a three-phase (ferrite, martensite and retained austenite) quenched and partitioned sheet steel with a tensile strength of ~980 MPa. The macroscopic flow behavior and the volume fraction of martensite resulting from the austenite–martensite transformation during deformation were measured. In addition, micropillar compression specimens were extracted from the individual ferrite grains and the martensite particles, and using a flat-punch nanoindenter, stress–strain curves were obtained. Finite element simulations idealize the microstructure as a composite that contains ferrite, martensite and retained austenite. All three phases are discretely modeled using appropriate crystal plasticity based constitutive relations. Material parameters for ferrite and martensite are determined by fitting numerical predictions to the micropillar data. The constitutive relation for retained austenite takes into account contributions to the strain rate from the austenite–martensite transformation, as well as slip in both the untransformed austenite and product martensite. Parameters for the retained austenite are then determined by fitting the predicted flow stress and transformed austenite volume fraction in a 3D microstructure to experimental measurements. Simulations are used to probe the role of the retained austenite in controlling the strain hardening behavior as well as internal stress and strain distributions in the microstructure.

Published

2015

73. Effect of finish cooling temperature on microstructure and mechanical properties of high-strength bainitic steels containing Cr, Mo, and B

Author

Byoungchul Hwang, Dong Ho Lee, Sang Yong Shin, Hyokyung Sung, Sunghak Lee, and Jang Yong Yoo

Subjects

Materials science, Bainite, Mechanical Engineering, Metallurgy, Charpy impact test, Condensed Matter Physics, Microstructure, Acicular ferrite, Grain size, Mechanics of Materials, Ferrite (iron), Volume fraction, Thermomechanical processing, General Materials Science, Composite material

Abstract

Six low-carbon high-strength bainitic steels containing Cr, Mo, and B were fabricated by controlling finish cooling temperature, and the effect of bainitic microstructure on tensile and Charpy impact properties were investigated. All the specimens were composed primarily of bainitic ferrite, together with small amounts of granular bainite, acicular ferrite, martensite–austenite constituent. These bainitic microstructures were more critically affected by the finish cooling temperature than by the alloying elements. The H-series specimens with a high finish cooling temperature had larger amount of acicular ferrite and smaller amount of granular bainite and bainitic ferrite, compared to the L-series specimens with the low finish cooling temperature at the same chemical composition. The L-series specimens exhibited higher strength and yield ratio, and lower uniform and total elongations than the H-series specimens because the volume fraction of BF was higher in the L-series specimens than in the H-series specimens. On the other hand, the energy transition temperature decreased with increasing the volume fraction of AF having fine effective grain size, while it increased with an increase in the volume fraction of GB having coarse effective grain size. Thus, the energy transition temperature of the H-series specimens with the high finish cooling temperature were slightly lower than that of the L-series specimens with the low finish cooling temperature because the H-series specimens had a larger amount of AF than the L-series specimens.

Published

2015

74. Cryogenic-temperature fracture toughness analysis of non-equi-atomic V10Cr10Fe45Co20Ni15 high-entropy alloy

Author

Donghwa Lee, Hyoung Seop Kim, Dae Woong Kim, Yong Hee Jo, Kyung-Yeon Doh, Seok Su Sohn, Kwanho Lee, Sunghak Lee, Dong Geun Kim, Hyokyung Sung, and Byeong-Joo Lee

Subjects

Toughness, Materials science, Mechanical Engineering, Alloy, Metals and Alloys, 02 engineering and technology, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Fracture toughness, Mechanics of Materials, Ultimate tensile strength, Materials Chemistry, engineering, Elongation, Composite material, 0210 nano-technology, Cryogenic temperature, Damage tolerance, Stacking fault

Abstract

Representative face-centered-cubic (FCC) high-entropy alloys (HEAs) or medium-entropy alloys (MEAs), e.g., equi-atomic CoCrFeMnNi or CrCoNi alloys, have drawn many attentions due to the excellent damage-tolerance at cryogenic temperature. The investigation of fracture toughness at 77 K is basically required for the reliable evaluation of high-performance alloys used for cryogenic applications; however, it has been rarely carried out for the non-equi-atomic FCC HEAs yet. In this study, tensile and fracture toughness tests were conducted on the non-equi-atomic V10Cr10Fe45Co20Ni15 alloy, and the results were compared with those of the equi-atomic CoCrFeMnNi and CrCoNi alloys. The present alloy shows a good damage tolerance at cryogenic temperature with tensile strength of 1 GPa and elongation of ∼60%. The KJIc fracture toughness values are 219 and 232 MPa m1/2 at 298 and 77 K, respectively, showing the increase in toughness with decreasing temperature. This increase results from the absence of twins at 298 K and the increased propensity to twin formation at 77 K, which is well confirmed by the variation of stacking fault energies (SFEs) by using Ab-initio calculations. The mechanical properties of the present alloy are actually similar or slightly lower than those of the other CoNiCr or FeMnCoNiCr alloy; instead, this study provides that neither composition nor certain elements are the most important factors dictating damage-tolerance of HEAs or MEAs.

Published

2019

75. Microstructural effects on the tensile and fracture behavior of selective laser melted H13 tool steel under varying conditions

Author

Junhyeok Park, Ji-Hun Yu, Hyokyung Sung, Im Doo Jung, Sangshik Kim, Jungsub Lee, and Jungho Choe

Subjects

010302 applied physics, Austenite, Materials science, Mechanical Engineering, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Mechanics of Materials, Martensite, 0103 physical sciences, Tool steel, Ultimate tensile strength, engineering, General Materials Science, Grain boundary, Selective laser melting, Composite material, 0210 nano-technology, Electron backscatter diffraction, Tensile testing

Abstract

The microstructural-mechanical correlative study has been conducted for characterization of selective laser melted H13 tool steel. Transformation behavior from austenite to martensite has been observed with partitioning of C in matrix with correlative atomic diffusivity during selective laser melting process. During solidification, columnar grain structures are formed due to epitaxial growth following the build direction of H13 tool steels. Columnar microstructures are mostly composed of martensite with small amount of retained austenite. Supercooling of H13 with high laser scan speed increased the nucleation sites, which reduced the diameter of columnar grain. During tensile test, deformation appeared in grain boundary while there was no significant martensitic phase transformation confirmed by X-ray diffraction (XRD) method and electron backscattered diffraction (EBSD) analysis. S2 (scan speed of 200 mm/s specimen had the better tensile property with tensile strength of 1700 MPa and elongation of 1.6% than the rest(

Published

2019

76. Effects of Start and Finish Cooling Temperatures on Microstructure and Mechanical Properties of Low-Carbon High-Strength and Low-Yield Ratio Bainitic Steels

Author

Sunghak Lee, Hyokyung Sung, and Sang Yong Shin

Subjects

Materials science, Volume (thermodynamics), Mechanics of Materials, Bainite, Ferrite (iron), Ultimate tensile strength, Volume fraction, Metallurgy, Metals and Alloys, Charpy impact test, Condensed Matter Physics, Microstructure, Acicular ferrite

Abstract

The effects of start and finish cooling temperatures on microstructure and mechanical properties of low-carbon high-strength and low-yield ratio bainitic steels were investigated in this study. Four kinds of low-carbon high-strength and low-yield ratio bainitic steels were fabricated by varying the start and finish cooling temperatures and cooling rates, and their microstructure and mechanical properties such as tensile and Charpy impact properties were measured. In the steels cooled down from the high start cooling temperature above Ar1 [978 K (705 °C)], the volume fraction of acicular ferrite is lower than in the steels cooled down from the low start cooling temperature below Ar1 [978 K (705 °C)]. The finish cooling temperatures and cooling rates affect the formation of bainitic ferrite, granular bainite, and martensite–austenite (MA) constituents. According to the correlation between microstructure and mechanical properties, the tensile strength increases with increasing the volume fractions of bainitic ferrite and MA constituents, whereas the elongation decreases. The yield ratio decreases as the volume fraction of MA constituents increases. Charpy impact absorbed energy is proportional to the volume fraction of acicular ferrite, and is inversely proportional to the volume fraction of granular bainite.

Published

2013

77. Influence of reduction ratio on the interface microstructure and mechanical properties of roll-bonded Al/Cu sheets

Author

Kisung Lee, Dong Ho Lee, Yongnam Kwon, Sukmook Lee, Jin Suk Kim, Hyokyung Sung, Seong Lee, and Young Won Chang

Subjects

Equiaxed crystals, Materials science, Mechanical Engineering, Metallurgy, Condensed Matter Physics, Reduction ratio, Microstructure, Roll bonding, Mechanics of Materials, Bonding strength, Fracture (geology), General Materials Science, Composite material, Elongation

Abstract

Two-ply Al/Cu sheets were prepared via roll bonding with different reduction ratios. Al/Cu sheets fabricated below 50% of reduction ratio exhibited relatively equiaxed grains without interface reaction, which resulted in weak joint-bonding strength. However, both strong metallurgical bonding at interface and fine, elongated grains from constituent alloys adjacent to the interface were successfully introduced under the reduction ratio of 65%, leading to a strongly enhanced bonding strength of 17.1 N/mm together with an increased elongation up to fracture by 28%.

Published

2013

78. Effects of Cooling Conditions on Microstructure, Tensile Properties, and Charpy Impact Toughness of Low-Carbon High-Strength Bainitic Steels

Author

Hyokyung Sung, Chang Gil Lee, Byoungchul Hwang, Sunghak Lee, and Sang Yong Shin

Subjects

Toughness, Materials science, Bainite, Metallurgy, Metals and Alloys, Charpy impact test, Condensed Matter Physics, Microstructure, Acicular ferrite, Mechanics of Materials, Ferrite (iron), Ultimate tensile strength, Volume fraction, Composite material

Abstract

In this study, four low-carbon high-strength bainitic steel specimens were fabricated by varying finish cooling temperatures and cooling rates, and their tensile and Charpy impact properties were investigated. All the bainitic steel specimens consisted of acicular ferrite, granular bainite, bainitic ferrite, and martensite-austenite constituents. The specimens fabricated with higher finish cooling temperature had a lower volume fraction of martensite-austenite constituent than the specimens fabricated with lower finish cooling temperature. The fast-cooled specimens had twice the volume fraction of bainitic ferrite and consequently higher yield and tensile strengths than the slow-cooled specimens. The energy transition temperature tended to increase with increasing effective grain size or with increasing volume fraction of granular bainite. The fast-cooled specimen fabricated with high finish cooling temperature and fast cooling rate showed the lowest energy transition temperature among the four specimens because of the lowest content of coarse granular bainite. These findings indicated that Charpy impact properties as well as strength could be improved by suppressing the formation of granular bainite, despite the presence of some hard microstructural constituents such as bainitic ferrite and martensite-austenite.

Published

2012

79. Effects of B and Cu Addition and Cooling Rate on Microstructure and Mechanical Properties in Low-Carbon, High-Strength Bainitic Steels

Author

Hyokyung Sung, Chang Gil Lee, Byoungchul Hwang, Sang Yong Shin, and Sunghak Lee

Subjects

Toughness, Acicular, Materials science, Bainite, Metallurgy, Metals and Alloys, Charpy impact test, Condensed Matter Physics, Microstructure, Acicular ferrite, Mechanics of Materials, Martensite, Ferrite (magnet), Composite material

Abstract

The effects of B and Cu addition and cooling rate on microstructure and mechanical properties of low-carbon, high-strength bainitic steels were investigated in this study. The steel specimens were composed mostly of bainitic ferrite, together with small amounts of acicular ferrite, granular bainite, and martensite. The yield and tensile strengths of all the specimens were higher than 1000 MPa and 1150 MPa, respectively, whereas the upper shelf energy was higher than 160 J and energy transition temperature was lower than 208 K (–65 °C) in most specimens. The slow-cooled specimens tended to have the lower strengths, higher elongation, and lower energy transition temperature than the fast-cooled specimens. The Charpy notch toughness was improved with increasing volume fraction of acicular ferrite because acicular ferrites favorably worked for Charpy notch toughness even when other low-toughness microstructures such as bainitic ferrite and martensite were mixed together. To develop high-strength bainitic steels with an excellent combination of strength and toughness, the formation of bainitic microstructures mixed with acicular ferrite was needed, and the formation of granular bainite was prevented.

Published

2012

80. Effects of finish rolling temperature on inverse fracture occurring during drop weight tear test of API X80 pipeline steels

Author

Seok Su Sohn, Hyokyung Sung, Nack J. Kim, Jang Yong Yoo, Seung Hwan Chon, Sunghak Lee, and Sang Yong Shin

Subjects

Materials science, Bainite, Mechanical Engineering, Metallurgy, Cleavage (crystal), Strain hardening exponent, Condensed Matter Physics, Microstructure, Acicular ferrite, law.invention, Mechanics of Materials, law, Volume fraction, Fracture (geology), General Materials Science, Hammer

Abstract

In this study, drop-weight tear tests (DWTT) were conducted on API X80 pipeline steels fabricated with different finish rolling temperatures in order to analyze abnormal fracture appearance, i.e ., inverse fracture, occurring in the region impacted by a hammer. Area fractions of fracture modes were measured from fractured DWTT specimens, and the measured data were analyzed in relation to microstructures, DWTT absorbed energy, and strain hardening of the hammer-impacted region. As the finish rolling temperature decreased, the volume fraction of fine-grained acicular ferrite increased, while that of large-grained upper bainite or granular bainite decreased. According to the DWTT results, the absorbed energy tended to increase with increasing volume fraction of acicular ferrite (with decreasing finish rolling temperature). A large area of inverse fracture of cleavage type was found in the hammer-impacted region of the steels fabricated with high finish rolling temperatures, but the area fraction of inverse fracture was reduced in the steels fabricated with low finish rolling temperatures. Since the area fraction of inverse fracture was closely related with strain hardening of the hammer-impacted region, it could be successfully reduced by lowering strain hardening and by promoting the formation of acicular ferrite via low finish rolling temperatures.

Published

2012

81. Effects of carbon equivalent and cooling rate on tensile and Charpy impact properties of high-strength bainitic steels

Author

Hyokyung Sung, Byoungchul Hwang, Sunghak Lee, Nack J. Kim, Chang Gil Lee, and Sang Yong Shin

Subjects

Materials science, Bainite, Mechanical Engineering, Metallurgy, Charpy impact test, Condensed Matter Physics, Microstructure, Acicular ferrite, Mechanics of Materials, Martensite, Ferrite (iron), Ultimate tensile strength, General Materials Science, Composite material, Ductility

Abstract

The effects of carbon equivalent and cooling rateon tensile and Charpy impact properties of high-strength bainitic steels were investigated. Eight steel plates were fabricated with varying C, Cr, and Nb additions under two different cooling rates, and their microstructures, tensile, and Charpy impact properties were evaluated. Volume fractions of microstructural components present in the steels increased in the order of granular bainite, acicular ferrite, bainitic ferrite, and martensite as the carbon equivalent or cooling rate increased, which resulted in decreased ductility and upper shelf energy and increased energy transition temperature in spite of increased strength. In the steels containing about 50 vol.% of bainitic ferrite and martensite, the tensile strength was about 900 MPa, while the elongation and upper shelf energy were about 20% and 200 J, respectively. In order to achieve the best combination of tensile strength, ductility, and upper shelf energy, e.g., 860–900 MPa, 20%, and 200 J, respectively, granular bainite, and acicular ferrite were produced by controlling the carbon equivalent and cooling rate, while about 50 vol.% of bainitic ferrite and martensite were maintained to keep the high strength.

Published

2011

82. Nano-Scaled Pt/Ag/Ni/Au Contacts on p-type GaN for Low Contact Resistance and High Reflectivity

Author

Ko Cg, Ju Ic, Seong Kyu Kim, Seunghyup Yoo, Kang Dh, Myung-Hyun Kim, Kwanwoo Shin, Kwon Yw, Yongseok Choi, and Hyokyung Sung

Subjects

Materials science, High reflectivity, Contact resistance, Biomedical Engineering, Analytical chemistry, Bioengineering, General Chemistry, Condensed Matter Physics, Metal, Wavelength, visual_art, Nano, visual_art.visual_art_medium, General Materials Science, Layer (electronics), Ohmic contact, Deposition (law)

Abstract

We synthesized the vertical-structured LED (VLED) using nano-scaled Pt between p-type GaN and Ag-based reflector. The metallization scheme on p-type GaN for high reflectance and low was the nano-scaled Pt/Ag/Ni/Au. Nano-scaled Pt (5 A) on Ag/Ni/Au exhibited reasonably high reflectance of 86.2% at the wavelength of 460 nm due to high transmittance of light through nano-scaled Pt (5 A) onto Ag layer. Ohmic behavior of contact metal, Pt/Ag/Ni/Au, to p-type GaN was achieved using surface treatments of p-type GaN prior to the deposition of contact metals and the specific contact resistance was observed with decreasing Pt thickness of 5 A, resulting in 1.5 x 10(-4) ohms cm2. Forward voltages of Pt (5 A)/Ag/Ni contact to p-type GaN showed 4.19 V with the current injection of 350 mA. Output voltages with various thickness of Pt showed the highest value at the smallest thickness of Pt due to its high transmittance of light onto Ag, leading to high reflectance. Our results propose that nano-scaled Pt/Ag/Ni could act as a promising contact metal to p-type GaN for improving the performance of VLEDs.

Published

2011

83. Effects of acicular ferrite on charpy impact properties in heat affected zones of oxide-containing API X80 linepipe steels

Author

Hyokyung Sung, Kyungshik Oh, Woo-Yeol Cha, Sunghak Lee, Sang Yong Shin, and Nack J. Kim

Subjects

Heat-affected zone, Acicular, Materials science, Mechanical Engineering, Metallurgy, Charpy impact test, Welding, Condensed Matter Physics, Microstructure, Acicular ferrite, law.invention, Mechanics of Materials, law, Ferrite (iron), Volume fraction, General Materials Science

Abstract

This study was concerned with effects of acicular ferrite on Charpy impact properties in heat affected zones (HAZs) of two API X80 linepipe steels containing oxides. In the one steel, Mg and O 2 were additionally added to form a larger amount of oxides than the other steel, which was a conventional X80 steel containing a considerable amount of Al and Ti. Various HAZ microstructures were obtained by conducting HAZ simulation tests under different heat inputs of 35 kJ cm −1 and 60 kJ cm −1 . Oxides present in the API X80 linepipe steels were complex oxides whose average size was 1–2 μm, and the number of oxides increased with increasing amount of Mg and O 2 . The volume fraction of acicular ferrite present in the steel HAZs increased with increasing number of oxides, and decreased with increasing heat input. When the volume fraction of acicular in the HAZ was higher than 20%, Charpy impact energy at −20 °C was higher than 100 J as the ductile fracture mode was dominant. Particularly in the steel HAZs having a larger amount of oxides, Charpy impact properties were excellent because oxides worked as nucleation sites of acicular ferrite during welding. Charpy impact properties of the HAZs could be well correlated with the volume fraction of acicular ferrite and number of oxides under different heat input conditions.

Published

2011

84. Effects of Rolling and Cooling Conditions on Microstructure and Tensile and Charpy Impact Properties of Ultra-Low-Carbon High-Strength Bainitic Steels

Author

Nack J. Kim, Sunghak Lee, Chang Gil Lee, Byoungchul Hwang, Hyokyung Sung, and Sang Yong Shin

Subjects

Austenite, Materials science, Carbon steel, Metallurgy, Metals and Alloys, Charpy impact test, engineering.material, Condensed Matter Physics, Microstructure, Acicular ferrite, Grain size, Mechanics of Materials, Ultimate tensile strength, engineering, Composite material, Ductility

Abstract

Six ultra-low-carbon high-strength bainitic steel plates were fabricated by controlling rolling and cooling conditions, and effects of bainitic microstructure on tensile and Charpy impact properties were investigated. The microstructural evolution was more critically affected by start cooling temperature and cooling rate than by finish rolling temperature. Bainitic microstructures such as granular bainites (GBs) and bainitic ferrites (BFs) were well developed as the start cooling temperature decreased or the cooling rate increased. When the steels cooled from 973 K or 873 K (700 °C or 600 °C) were compared under the same cooling rate of 10 K/s (10 °C/s), the steels cooled from 973 K (700 °C) consisted mainly of coarse GBs, while the steels cooled from 873 K (600 °C) contained a considerable amount of BFs having high strength, thereby resulting in the higher strength but the lower ductility and upper shelf energy (USE). When the steels cooled from 673 K (400 °C) at a cooling rate of 10 K/s (10 °C/s) or 0.1 K/s (0.1 °C/s) were compared under the same start cooling temperature of 873 K (600 °C), the fast cooled specimens were composed mainly of coarse GBs or BFs, while the slowly cooled specimens were composed mainly of acicular ferrites (AFs). Since AFs had small effective grain size and contained secondary phases finely distributed at grain boundaries, the slowly cooled specimens had a good combination of strength, ductility, and USE, together with very low energy transition temperature (ETT).

Published

2010

85. Charpy Impact Properties of Heat Affected Zones of API X80 Linepipe Steels Containing Complex Oxides

Author

Hyokyung Sung, Nack J. Kim, Kyungshik Oh, Sunghak Lee, Woo-Yeol Cha, and Sang Yong Shin

Subjects

Materials science, Energy absorbing, Modeling and Simulation, Metallurgy, Volume fraction, Metals and Alloys, Nucleation, Charpy impact test, Microstructure, Acicular ferrite, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

This study assessed the Charpy impact properties of the heat-affected zones (HAZs) of API X80 linepipe steels containing complex oxides. Three types of steel were fabricated by adding Mg and O2 to form complex oxides and their microstructures and Charpy impact properties were investigated. The number of complex oxides increased with the amount of excess Mg and O2 that was included in the steels. Simulated HAZs containing a number of oxides showed a high volume fraction of acicular ferrite (AF) because the oxides acted as nucleation sites for AF, thereby leading to an improvement in the Charpy impact properties. According to a correlation study between the heat input, the volume fraction of the AF, and the Charpy impact properties, ductile fractures occurred predominantly when the fraction of the AF was 20% or higher; moreover, the Charpy absorbed energy was excellent at more than 100 J. These findings suggest that the improvement of the Charpy impact properties of the HAZs was associated with the active nucleation of AF in the oxidecontaining steel HAZs. (Received March 17, 2010)

Published

2010

86. Effects of Alloying Elements on Microstructure, Hardness, Wear Resistance, and Surface Roughness of Centrifugally Cast High-Speed Steel Rolls

Author

Sunghak Lee, Dae Jin Ha, Hyokyung Sung, and Joon Wook Park

Subjects

Materials science, Metallurgy, Metals and Alloys, Surface finish, Lath, engineering.material, Tribology, Condensed Matter Physics, Microstructure, Carbide, Mechanics of Materials, Martensite, Surface roughness, engineering, High-speed steel

Abstract

A study was made of the effects of carbon, tungsten, molybdenum, and vanadium on the wear resistance and surface roughness of five high-speed steel (HSS) rolls manufactured by the centrifugal casting method. High-temperature wear tests were conducted on these rolls to experimentally simulate the wear process during hot rolling. The HSS rolls contained a large amount (up to 25 vol pct) of carbides, such as MC, M2C, and M7C3 carbides formed in the tempered martensite matrix. The matrix consisted mainly of tempered lath martensite when the carbon content in the matrix was small, and contained a considerable amount of tempered plate martensite when the carbon content increased. The high-temperature wear test results indicated that the wear resistance and surface roughness of the rolls were enhanced when the amount of hard MC carbides formed inside solidification cells increased and their distribution was homogeneous. The best wear resistance and surface roughness were obtained from a roll in which a large amount of MC carbides were homogeneously distributed in the tempered lath martensite matrix. The appropriate contents of the carbon equivalent, tungsten equivalent, and vanadium were 2.0 to 2.3, 9 to 10, and 5 to 6 pct, respectively.

Published

2009

87. Analysis and prevention of sticking occurring during hot rolling of ferritic stainless steel

Author

Hyokyung Sung, Yong Deuk Lee, Sunghak Lee, Jong Seog Lee, and Dae Jin Ha

Subjects

Sticking coefficient, Materials science, Mechanical Engineering, Metallurgy, Oxide, Condensed Matter Physics, Hardness, chemistry.chemical_compound, chemistry, Mechanics of Materials, Volume fraction, Lubrication, General Materials Science, Surface layer, Layer (electronics), Rolling speed

Abstract

Sticking phenomena occurring during hot rolling of a modified STS 430J1L ferritic stainless steel were investigated in this study by using a pilot-plant-scale rolling machine. As the rolling pass proceeded, the Fe-Cr oxide layer formed in a reheating furnace was destroyed, and the destroyed oxides infiltrated into the rolled steel to form a thin oxide layer in the surface region. The sticking did not occur in the surface region containing oxides, whereas it occurred in the surface region without oxides by the separation of the rolled steel at high temperatures. This indicated that the resistance to sticking increased by the increase in the surface hardness when a considerable amount of oxides were formed in the surface region, and that the sticking could be evaluated by the volume fraction and distribution of oxides formed in the surface region. The lubrication and the increase of the rolling speed and rolling temperature beneficially affected to the resistance to sticking because they accelerated the formation of oxides on the steel surface region. In order to prevent or minimize the sticking, thus, it was suggested to increase the thickness of the oxide layer formed in the reheating furnace and to homogeneously distribute oxides along the surface region by controlling the hot-rolling process.

Published

2009

88. Erratum to: Effect of superplastic forming exposure on tensile and S-N fatigue behavior of Ti64 alloy

Author

Hyokyung Sung, Yongnam Kwon, Sangshik Kim, and Daeho Jeong

Subjects

Materials science, 020502 materials, Metallurgy, Alloy, Metals and Alloys, Superplasticity, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0205 materials engineering, Mechanics of Materials, Solid mechanics, Metallic materials, Ultimate tensile strength, Materials Chemistry, engineering, Composite material, 0210 nano-technology

Published

2016

89. Performance of GaN vertical light emitting diodes using wafer bonding process with Al-alloyed graphite substrate

Author

Lee Bo, Min-Ho Park, Ko Cg, Ju Ic, Hyokyung Sung, Kwanwoo Shin, JeHyuk Choi, Kwon Yw, and Kim Sk

Subjects

Materials science, Wafer bonding, business.industry, Biomedical Engineering, Bioengineering, General Chemistry, Condensed Matter Physics, Laser, Thermal expansion, law.invention, law, Plating, Sapphire, Optoelectronics, General Materials Science, Wafer, Graphite, business, Light-emitting diode

Abstract

We report on the vertical-structure light emitting diodes (VLEDs) fabricated with wafer bonding method using Al-alloyed graphite and Si supporter. VLEDs with Al-alloyed graphite produced no crack during/after laser lift-off (LLO) techniques while the wafer crack took place using Si supporter because of the difference of thermal expansion coefficients between Si and sapphire. The performance of VLEDs with wafer bonding method using Al-alloyed graphite supporter was compared to those fabricated by Cu plating methods. The output power of the chips with wafer bonding method was nearly same as the one with Cu-plating method. However, the forward voltage of VLEDs with wafer bonding method was higher than those with Cu-plating method. In the terms of reliabilities the wafer bonding process is more preferable to Cu-plating and our report proposes that Al-alloyed graphite could be one of promising candidates for the supporters in wafer bonding process.

Published

2011

90. Effects of Alloying Elements and the Cooling Condition on the Microstructure, Tensile Properties, and Charpy Impact Properties of High-Strength Bainitic Steels

Author

Chang Gil Lee, Hyokyung Sung, Lee Sung Hak, Kim Nack Joon, Byoungchul Hwang, and Sangyong Shin

Subjects

Austenite, Materials science, Modeling and Simulation, Ultimate tensile strength, Metals and Alloys, Charpy impact test, Deformation (meteorology), Composite material, Microstructure, Acicular ferrite, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Published

2010