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1. Rate-dependent serration behavior of twinning-induced plasticity steel at ultra-low temperature

Author

Taeho Lee, Chetan Singh, You Sub Kim, Dong-Hyun Lee, Jun Hyun Han, Jun-Yun Kang, and Soo Yeol Lee

Subjects
High-Mn steel, Cryogenic temperature, Strain rate, Twin, Serration, Mining engineering. Metallurgy, TN1-997
Abstract

This study investigates the strain rate-dependent deformation behavior of cost-effective twinning-induced plasticity (TWIP) steel, Fe–26Mn-0.4C, at 15 K and reveals intriguing insights into its mechanical properties. The serration type changes from type A to type C with decreasing strain rate, resulting in a quasi-cleavage fracture at the crack initiation site. Microstructural analysis unveils a correlation between strain rate and the evolution of bundle twins, nano-twins, and ε-martensites. These denser networks of deformation twins (DTs) and ε-martensites contribute to impacting the mechanical properties. The mechanism behind the formation of serrations involves a rate-dependent thermal instability effect and the intricate interactions between dislocations and dislocations/Mn–C couples. The distinct findings enhance our understanding of the complex deformation behavior of high-Mn steel at cryogenic temperatures and provide valuable insights into the broader field of high-Mn steel applications in dynamic environments.

Published
2024
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2. Mechanical properties of base metal and heat-affected zone in friction-stir-welded AA6061-T6 at ultra-low temperature of 20 K

Author

Thanh-Dat Nguyen, Chetan Singh, You Sub Kim, Jun Hyun Han, Dong-Hyun Lee, Kwangjin Lee, Stefanus Harjo, and Soo Yeol Lee

Subjects
Aluminum alloy, Friction stir welding, Heat-affected zone, Ultra-low temperature, Neutron diffraction, Mining engineering. Metallurgy, TN1-997
Abstract

This study investigates the mechanical properties of a friction-stir-welded (FSW) AA6061-T6 aluminum alloy at ultra-low temperature (ULT) of 20 K. In-situ neutron diffraction and orientation imaging microscopy were employed to compare the tensile deformation behavior of the base metal (BM) and heat-affected zone (HAZ) in the FSW aluminum plate. The results demonstrate that compared to room-temperature (RT), ULT induces a significant improvement in tensile strength and ductility in both the BM and HAZ. The enhanced mechanical properties in BM at ULT result from a more homogeneous deformation than occurs at RT. On the other hand, HAZ at ULT exhibits an even lower yield strength than at RT, but the strain hardening rate (SHR) is the most significant among the alloys, leading to a tensile strength of 346 MPa and the highest ductility of 46.8%. The lowest yield strength corresponds to the lowest-hardness zones in HAZ, caused by dissolved/coarsened precipitates during the FSW process. The highest SHR in HAZ at ULT is attributed to the hardening of the {111} grain families and finer dislocation cell structures. The dislocation densities of both the BM and HAZ increased considerably during tensile deformation at ULT, which accounts for the improvement in tensile strength. Revealing the mechanism behind the remarkable improvement in the mechanical properties of FSW AA6061-T6 at ULT suggests its applicability for cryogenic applications.

Published
2024
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3. Room and cryogenic deformation behavior of AZ61 and AZ61-xCaO (x = 0.5, 1 wt.%) alloy

Author

Umer Masood Chaudry, Hafiz Muhammad Rehan Tariq, Nooruddin Ansari, Soo Yeol Lee, and Tea-Sung Jun

Subjects
Magnesium, Twinning, Twinning variant, EBSD, Cryogenic deformation, Mining engineering. Metallurgy, TN1-997
Abstract

This study investigates the influence of CaO (0.5, 1 (wt.%)) alloying on the microstructural evolution, texture development and deformation behavior of AZ61 magnesium alloy. The uniaxial tension tests at room (RT) and cryogenic (CT, -150 °C) temperature were performed to investigate the twinability and dislocation behavior and its consequent effect on flow stress, ductility and strain hardening rate. The results showed that the AZ61-1CaO exhibited superior strength/ductility synergy at RT with a yield strength (YS) of 223 MPa and a ductility of 23% as compared to AZ61 (178 MPa, 18.5%) and AZ61-0.5CaO (198 MPa, 21%). Similar trend was witnessed for all the samples during CT deformation, where increase in the YS and decrease in ductility were observed. The Mtex tools based in-grain misorientation axis (IGMA) analysis of RT deformed samples revealed the higher activities of prismatic slip in AZ61-CaO, which led to superior ductility. Moreover, subsequent EBSD analysis of CT deformed samples showed the increased fraction of fine {10-12} tension twins and nucleation of multiple {10-12} twin variants caused by higher local stress concentration at the grain boundaries, which imposed the strengthening by twin-twin interaction. Lastly, the detailed investigations on strengthening contributors showed that the dislocation strengthening has the highest contribution towards strength in all samples.

Published
2024
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4. Bimodal reinforcement of graphite flake and graphene nanoplatelet in Cu matrix composites: Anisotropy of the thermo-mechanical properties and failure mechanisms

Author

Jun Zhang, Sang Hun Shim, Hyeyoung Cho, Donggil Lee, Soo Yeol Lee, Jae-Pyoung Ahn, and Jun Hyun Han

Subjects
GF/Cu composite, Graphene nanoplatelet (GNP), Bimodal reinforcement, Coefficient of thermal expansion (CTE), Mechanical property, Mining engineering. Metallurgy, TN1-997
Abstract

Bimodal reinforcement consisting of powders of large graphite flake (GF) and small graphene nanoplatelet (GNP) were used to fabricate (GF + GNP)/Cu composites to reduce the anisotropy of the thermal and mechanical properties in GF/Cu composites. In this study, we investigated the effects of GNP addition on the anisotropy of the thermal and mechanical properties and the deformation behavior of (GF + GNP)/Cu composites. The 2 θ > value was used to evaluate the alignment of the reinforcing phases (GF, GNP), by which the variations in the coefficient of thermal expansion (CTE) and thermal conductivity (TC) of the composites were analyzed. With increasing GNP volume fraction, the angle (θ) at which the GF deviated from the in-plane direction increased. As a result, the anisotropy of the CTE in the in-plane and through-plane directions increased, whereas the anisotropy of the TC and mechanical strength decreased. Cracking was observed in both the specimens compressed along the in-plane and through-plane directions, whereas kinking was observed only in the specimens compressed along the in-plane direction. The deformation behavior and mechanical properties of the composites with bimodal reinforcement in the in-plane and through-plane directions were strongly dependent on the change in the alignment of the GF with the addition of GNP. The results clearly revealed the role of bimodal reinforcement in controlling the anisotropy of the thermal and mechanical properties of the (GF + GNP)/Cu composite, providing guidelines for optimizing the thermomechanical properties of high-performance (GF + GNP)/Cu composites.

Published
2023
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5. Anisotropic microstructure, nanomechanical and corrosion behavior of direct energy deposited Ti–13Nb–13Zr biomedical alloy

Author

Nooruddin Ansari, Dong-Hyun Lee, E-Wen Huang, Jayant Jain, and Soo Yeol Lee

Subjects
Ti–13Nb–13Zr alloy, Direct energy deposition, Indentation strain rate sensitivity, Indentation creep, Corrosion, Mining engineering. Metallurgy, TN1-997
Abstract

The present study investigates the anisotropic microstructure, nanomechanical and corrosion behavior of Ti–13Nb–13Zr biomedical alloys, which were fabricated using the direct energy deposition (DED) method. The microstructure of the as-deposited material was studied using a field-emission scanning electron microscope (SEM), electron backscatter diffraction (EBSD) and X-ray diffraction (XRD). We found anisotropic mechanical behavior using nanoindentation from strain rate sensitivity and creep tests. For the maximum load of 50 mN, the x-y plane (normal to the building direction) shows better indentation hardness and lower strain rate sensitivity value (0.014) compared to the x-z plane (0.022) (parallel to the building direction). The difference in the indentation hardness was mainly attributed to the smaller equiaxed prior-β grains and finer α’ martensitic laths on the x-y plane. In terms of creep behavior, the x-y planes show better creep strength than the x-z plane. Meanwhile, both planes show a very high creep exponent, which signifies a similar creep mechanism, i.e., dislocation based. Moreover, we further found the anisotropic corrosion behavior using electrochemical tests. Corrosion results reveal that the x-y plane is more corrosion-resistant than the x-z plane. In summary, the x-y plane of the direct energy deposited Ti–13Nb–13Zr alloy possesses better strength and corrosion resistance due to its finer microstructure.

Published
2023
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6. Effects of pre/post-aging treatment on the mechanical properties and texture of asymmetrically rolled 6061 aluminum alloy: formability and planar anisotropy

Author

Wonkee Chae, Minkyung Jeong, Donggil Lee, Jongbeom Lee, Dong Won Chun, Soo Yeol Lee, Soon-Ku Hong, Su Hyeon Kim, and Jun Hyun Han

Subjects
6061 Al alloy, Asymmetric rolling, Aging, Texture, Formability, Planar anisotropy, Mining engineering. Metallurgy, TN1-997
Abstract

6061 aluminum (Al) alloys were asymmetrically rolled to apply shear deformation, and the effects of pre/post-aging treatment on the mechanical properties and texture evolution were analyzed. The texture was analyzed using electron backscattered diffraction (EBSD), and the formability and planar anisotropy of the specimen were evaluated using the r¯-value and Δr-value calculated from the plastic strain ratios (r-values). Regardless of the aging conditions (no aging, pre-aging, and post-aging), asymmetric rolling yielded higher strength than symmetric rolling. Pre-aged specimens, regardless of the rolling method (symmetric rolling or asymmetric rolling), exhibited higher strength than the post-aged specimens. To develop the //ND shear texture throughout the specimen, asymmetric rolling in a supersaturated solid solution without an initial precipitate was more effective than asymmetrically rolling an aged-hardened specimen. Considering the strength, formability (r¯-value), and planar anisotropy (Δr-value) of the 6061 Al alloy, the asymmetrically rolled pre-aged specimen had the best mechanical properties. These results show that the strength and formability of the 6061 Al alloy can be improved and its planar anisotropy can be reduced using a combination of asymmetric rolling and control of the aging sequence. This work demonstrates how the deformation and heat treatment of Al alloys could be used to increase the adoptability of Al alloys for automobiles.

Published
2023
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7. 3D Digital Modeling of Dental Casts from Their 3D CT Images with Scatter and Beam-Hardening Correction

Author

Mohamed A. A. Hegazy, Myung Hye Cho, Min Hyoung Cho, and Soo Yeol Lee

Subjects
dental 3D modeling, CBCT, dental casts, scatter artifacts, beam-hardening artifacts, Chemical technology, TP1-1185
Abstract

Dental 3D modeling plays a pivotal role in digital dentistry, offering precise tools for treatment planning, implant placement, and prosthesis customization. Traditional methods rely on physical plaster casts, which pose challenges in storage, accessibility, and accuracy, fueling interest in digitization using 3D computed tomography (CT) imaging. We introduce a method that can reduce both artifacts simultaneously. To validate the proposed method, we carried out CT scan experiments using plaster dental casts created from dental impressions. After the artifact correction, the CT image quality was greatly improved in terms of image uniformity, contrast-to-noise ratio (CNR), and edge sharpness. We examined the correction effects on the accuracy of the 3D models generated from the CT images. As referenced to the 3D models derived from the optical scan data, the root mean square (RMS) errors were reduced by 8.8~71.7% for three dental casts of different sizes and shapes. Our method offers a solution to challenges posed by artifacts in CT scanning of plaster dental casts, leading to enhanced 3D model accuracy. This advancement holds promise for dental professionals seeking precise digital modeling for diverse applications in dentistry.

Published
2024
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8. Deciphering Hydrogen Embrittlement Mechanisms in Ti6Al4V Alloy: Role of Solute Hydrogen and Hydride Phase

Author

Tien-Dung Nguyen, Chetan Singh, Dong-Hyun Lee, You Sub Kim, Taeho Lee, and Soo Yeol Lee

Subjects
Ti6Al4V, hydrogen embrittlement, solute hydrogen, hydride phase, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

Ti6Al4V (Ti64) is a versatile material, finding applications in a wide range of industries due to its unique properties. However, hydrogen embrittlement (HE) poses a challenge in hydrogen-rich environments, leading to a notable reduction in strength and ductility. This study investigates the complex interplay of solute hydrogen (SH) and hydride phase (HP) formation in Ti64 by employing two different current densities during the charging process. Nanoindentation measurements reveal distinct micro-mechanical behavior in base metal, SH, and HP, providing crucial insights into HE mechanisms affecting macro-mechanical behavior. The fractography and microstructural analysis elucidate the role of SH and HP in hydrogen-assisted cracking behaviors. The presence of SH heightens intergranular cracking tendencies. In contrast, the increased volume of HP provides sites for crack initiation and propagation, resulting in a two-layer brittle fracture pattern. The current study contributes to a comprehensive understanding of HE in Ti6Al4V, essential for developing hydrogen-resistant materials.

Published
2024
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9. Effect of Strain Rate on Hydrogen Embrittlement of Ti6Al4V Alloy

Author

Tien-Dung Nguyen, Nooruddin Ansari, Keun Hyung Lee, Dong-Hyun Lee, Jun Hyun Han, and Soo Yeol Lee

Subjects
Ti6Al4V alloy, hydrogen embrittlement, strain rate, solute hydrogen, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

The phenomenon of hydrogen embrittlement (HE) in metals and alloys, which determines the performance of components in hydrogen environments, has recently been drawing considerable attention. This study explores the interplay between strain rates and solute hydrogen in inducing HE of Ti6Al4V alloy. For the hydrogen-charged sample, as the strain rate was decreased from 10−2/s to 10−5/s, the ductility decreased significantly, but the HE effect on mechanical strength was negligible. The low strain rate (LSR) conditions facilitated the development of high-angle grain boundaries, providing more pathways for hydrogen diffusion and accumulation. The presence of solute hydrogen intensified the formation of nano/micro-voids and intergranular cracking tendencies, with micro-crack occurrences observed exclusively in the LSR conditions. These factors expanded the brittle hydrogen-damaged region more deeply into the interior of the lattice. This, in turn, accelerated both crack initiation and intergranular crack propagation, finally resulting in a considerable HE effect and a reduction in ductility at the LSR. The current study underscores the influence of strain rate on HE, enhancing the predictability of longevity and improving the reliability of components operating in hydrogen-rich environments under various loading conditions.

Published
2024
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10. Optimization of Aging Temperature and Heat-Treatment Pathways in Additively Manufactured 17-4PH Stainless Steel

Author

Hobyung Chae, Sangyeob Lim, Taeho Lee, Eunjoo Shin, Joowon Suh, Suk Hoon Kang, and Soo Yeol Lee

Subjects
additive manufacturing, 17-4PH stainless steel, heat-treatment, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

This study investigates the tensile behaviors of additively manufactured (AM) 17-4PH stainless steels heat-treated within various temperature ranges from 400 °C to 700 °C in order to identify the effective aging temperature. Despite an aging treatment of 400–460 °C increasing the retained austenite content, an enhancement of the tensile properties was achieved without a strength-ductility trade-off owing to precipitation hardening by the Cu particles. Due to the intricate evolution of the microstructure, aging treatments above 490 °C led to a loss in yield strength and ductility. A considerable rise in strength and a decrease in ductility were brought about by the increase in the fraction of precipitation-hardened martensitic matrix in aging treatments over 640 °C. The impact of heat-treatment pathways on aging effectiveness and tensile anisotropy was then examined. Direct aging at 482 °C for an hour had hardly any effect on wrought 17-4PH, but it increased the yield strength of AM counterparts from 436–457 to 588–604 MPa. A solid-solution treatment at 1038 °C for one hour resulted in a significant drop in the austenite fraction, which led to an increase in the yield (from 436–457 to 841–919 MPa) and tensile strengths (from 1106–1127 to 1254–1256 MPa) with a sacrifice in ductility. Improved strength and ductility were realized by a solid-solution followed by an aging treatment, achieving 1371–1399 MPa. The tensile behaviors of AM 17-4PH were isotropic both parallel and perpendicular to the building direction.

Published
2023
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11. Overcoming brittleness of high volume fraction Al/SiCp composites by controlling interface characteristics

Author

Taegyu Lee, Hobyung Chae, Sangmin Shin, Seungchan Cho, Sang-Kwan Lee, Soo Yeol Lee, Ke An, and Ho Jin Ryu

Subjects
Metal matrix composites (MMCs), Mechanical behavior, Plasticity, Ductilization, Interface modification, Neutron diffraction, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

Particle-reinforced metal matrix composites (MMCs) with high-volume-fraction of above 40% are highly attractive in the field of structural materials because they impart enhanced reinforcement properties to metals. However, high-volume-fraction MMCs are not widely used due to their brittleness. Therefore, overcoming the brittleness of the high-volume-fraction composites is the first step to disseminate the high-reinforcement-fraction composites. In this study, the interface bonding of 55 vol% Al/SiCp composites was strengthened by modifying the interface characteristics to achieve high plasticity of the high-volume-fraction composite. The interface bonding strengthening was conducted by thermal oxidation of SiCp reinforcement. The increased plasticity of the composites was observed as the 62.2% increased fracture strain in the compression test. The interface modification changed the crack path during a compression test from interface crack to reinforcement particle crack. To investigate the mechanism of interface modification, in-situ neutron diffraction experiments were performed under compression. When the plasticity is enhanced by the interface treatment, most fractures consist of reinforcement fractures rather than interface fractures. Therefore, it is confirmed that controlling the interface treatment is a key factor to improve the plasticity in high-volume-fraction composites. This work shed light on developing new composite material with high-volume-fraction reinforcement.

Published
2022
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12. Tailoring grain sizes of the biodegradable iron-based alloys by pre-additive manufacturing microalloying

Author

Chih-Chieh Huang, Tu-Ngoc Lam, Lia Amalia, Kuan-Hung Chen, Kuo-Yi Yang, M. Rifai Muslih, Sudhanshu Shekhar Singh, Pei-I. Tsai, Yuan-Tzu Lee, Jayant Jain, Soo Yeol Lee, Hong-Jen Lai, Wei-Chin Huang, San-Yuan Chen, and E-Wen Huang

Subjects
Medicine, Science
Abstract

Abstract We demonstrated the design of pre-additive manufacturing microalloying elements in tuning the microstructure of iron (Fe)-based alloys for their tunable mechanical properties. We tailored the microalloying stoichiometry of the feedstock to control the grain sizes of the metallic alloy systems. Two specific microalloying stoichiometries were reported, namely biodegradable iron powder with 99.5% purity (BDFe) and that with 98.5% (BDFe-Mo). Compared with the BDFe, the BDFe-Mo powder was found to have lower coefficient of thermal expansion (CTE) value and better oxidation resistance during consecutive heating and cooling cycles. The selective laser melting (SLM)-built BDFe-Mo exhibited high ultimate tensile strength (UTS) of 1200 MPa and fair elongation of 13.5%, while the SLM-built BDFe alloy revealed a much lower UTS of 495 MPa and a relatively better elongation of 17.5%, indicating the strength enhancement compared with the other biodegradable systems. Such an enhanced mechanical behavior in the BDFe-Mo was assigned to the dominant mechanism of ferrite grain refinement coupled with precipitate strengthening. Our findings suggest the tunability of outstanding strength-ductility combination by tailoring the pre-additive manufacturing microalloying elements with their proper concentrations.

Published
2021
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13. Diffraction-based Residual Stress Mapping of a Stress Frame of Gray Iron via Vibratory Stress Relief Method

Author

Shi-Wei Chen, E-Wen Huang, Sung-Mao Chiu, Mark Reid, Cheng-Yen Wu, Anna M. Paradowska, Tu-Ngoc Lam, Yu-Hao Wu, Soo Yeol Lee, Shao-Chien Lu, Shin-An Chen, Yan-Gu Lin, and Shih-Chang Weng

Subjects
gray iron, residual stress, synchrotron X-ray, neutron diffraction, machine tools + design, Technology
Abstract

The role of residual stress is critical, particularly for machine tools demanding accuracy below 1 µm. Although minor stresses are subjected to a tiny area, the applied force can cause devastating distortions on the precision components at this length scale. In this research, we systematically investigated the residual stress in a stress frame of the gray iron used in machine tools using synchrotron X-ray and neutron sources. Through the combination of these techniques, the residual stresses on the surface, inside the bulk, and in average were presented. Comprehensive analysis results shed light on the vibratory stress relief technique, which reduced the residual stresses and stabilized them, even materials undergoing cycling heating. Although compressive stresses are not effectively reduced, this technique is useful in improving the mechanical stability of the materials in machine tools.

Published
2022
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14. Metal Artifact Reduction in Dental CBCT Images Using Direct Sinogram Correction Combined with Metal Path-Length Weighting

Author

Mohamed A. A. Hegazy, Myung Hye Cho, Min Hyoung Cho, and Soo Yeol Lee

Subjects
metal artifact reduction, beam hardening, direct sinogram correction, dental CBCT, metal segmentation, Chemical technology, TP1-1185
Abstract

Metal artifacts in dental computed tomography (CT) images, caused by highly X-ray absorbing objects, such as dental implants or crowns, often more severely compromise image readability than in medical CT images. Since lower tube voltages are used for dental CTs in spite of the more frequent presence of metallic objects in the patient, metal artifacts appear more severely in dental CT images, and the artifacts often persist even after metal artifact correction. The direct sinogram correction (DSC) method, which directly corrects the sinogram using the mapping function derived by minimizing the sinogram inconsistency, works well in the case of mild metal artifacts, but it often fails to correct severe metal artifacts. We propose a modified DSC method to reduce severe metal artifacts, and we have tested it on human dental images. We first segment the metallic objects in the CT image, and then we forward-project the segmented metal mask to identify the metal traces in the projection data with computing the metal path length for the rays penetrating the metal mask. In the sinogram correction with the DSC mapping function, we apply the weighting proportional to the metal path length. We have applied the proposed method to the phantom and patient images taken at the X-ray tube voltage of 90 kVp. We observed that the proposed method outperforms the original DSC method when metal artifacts were severe. However, we need further extensive studies to verify the proposed method for various CT scan conditions with many more patient images.

Published
2023
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15. Hydrogen Embrittlement of a Boiler Water Wall Tube in a District Heating System

Author

You Sub Kim, Woo Cheol Kim, Jayant Jain, E-Wen Huang, and Soo Yeol Lee

Subjects
boiler water wall tube, failure analysis, hydrogen embrittlement, stress corrosion cracking, Mining engineering. Metallurgy, TN1-997
Abstract

A district heating system is an eco-friendly power generation facility with high energy efficiency. The boiler water wall tube used in the district heating system is exposed to extremely harsh conditions, and unexpected fractures often occur during operation. In this study, a corrosion failure analysis of the boiler water wall tube was performed to elucidate the failure mechanisms. The study revealed that overheating by flames was the cause of the failure of the boiler water wall tube. With an increase in temperature in a localized region the microstructure not only changed from ferrite/pearlite to martensite/bainite, which made it more susceptible to brittleness, but it also developed tensile residual stresses in the water-facing side by generating cavities or microcracks along the grain boundaries inside the tube. High-temperature hydrogen embrittlement combined with stress corrosion cracking initiated many microcracks inside the tube and created an intergranular fracture.

Published
2022
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16. Effect of chemical dilution and the number of weld layers on residual stresses in a multi-pass low-transformation-temperature weld

Author

Huai Wang, Wanchuck Woo, Dong-Kyu Kim, Vyacheslav Em, and Soo Yeol Lee

Subjects
Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

Influences of chemical dilution and the number of weld layers on residual stresses in a multi-pass low-transformation-temperature (LTT) weld were investigated by finite element modelling and neutron diffraction. A coupled thermal-metallurgical-mechanical (TMM) model that took into account the chemical dilution effect was developed to simulate the complex LTT welding phenomena. The model was strictly validated by comparing the predictions with experimental measurements and the results found good agreement between them. The results showed that a transformation strain caused by LTT martensitic transformation introduced large compressive residual stresses (−500 MPa) into the weld zone and the quantities were closely related to the chemical dilution between welding layers. Simulation results revealed that the chemical dilution helped mitigate the large localized tensile residual stresses by modulating the phase transformation process and a single LTT layer was sufficient to generate high compression near the weld surface (~2.5 mm), which suggests a great importance for repair welding. Keywords: Finite element analysis, Thermal-metallurgical-mechanical model, Martensitic transformation, Residual stress, Chemical dilution, Multi-pass weld

Published
2018
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17. Microstructural Evolution and Mechanical Properties of Non-Equiatomic (CoNi)74.66Cr17Fe8C0.34 High-Entropy Alloy

Author

You Sub Kim, Hobyung Chae, E-Wen Huang, Jayant Jain, Stefanus Harjo, Takuro Kawasaki, Sun Ig Hong, and Soo Yeol Lee

Subjects
high-entropy alloy, mechanical property, stacking fault energy, neutron diffraction, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

In this study, we manufactured a non-equiatomic (CoNi)74.66Cr17Fe8C0.34 high-entropy alloy (HEA) consisting of a single-phase face-centered-cubic structure. We applied in situ neutron diffraction coupled with electron backscattered diffraction (EBSD) and transmission electron microscopy (TEM) to investigate its tensile properties, microstructural evolution, lattice strains and texture development, and the stacking fault energy. The non-equiatomic (CoNi)74.66Cr17Fe8C0.34 HEA revealed a good combination of strength and ductility in mechanical properties compared to the equiatomic CoNiCrFe HEA, due to both stable solid solution and precipitation-strengthened effects. The non-equiatomic stoichiometry resulted in not only a lower electronegativity mismatch, indicating a more stable state of solid solution, but also a higher stacking fault energy (SFE, ~50 mJ/m2) due to the higher amount of Ni and the lower amount of Cr. This higher SFE led to a more active motion of dislocations relative to mechanical twinning, resulting in severe lattice distortion near the grain boundaries and dislocation entanglement near the twin boundaries. The abrupt increase in the strain hardening rate (SHR) at the 1~3% strain during tensile deformation might be attributed to the unusual stress triaxiality in the {200} grain family. The current findings provide new perspectives for designing non-equiatomic HEAs.

Published
2022
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18. Cone-Beam Angle Dependency of 3D Models Computed from Cone-Beam CT Images

Author

Myung Hye Cho, Mohamed A. A. Hegazy, Min Hyoung Cho, and Soo Yeol Lee

Subjects
cone-beam dental CT, cone-beam artifact, digital impression, half-scan image reconstruction, stereolithography, Chemical technology, TP1-1185
Abstract

Cone-beam dental CT can provide high-precision 3D images of the teeth and surrounding bones. From the 3D CT images, 3D models, also called digital impressions, can be computed for CAD/CAM-based fabrication of dental restorations or orthodontic devices. However, the cone-beam angle-dependent artifacts, mostly caused by the incompleteness of the projection data acquired in the circular cone-beam scan geometry, can induce significant errors in the 3D models. Using a micro-CT, we acquired CT projection data of plaster cast models at several different cone-beam angles, and we investigated the dependency of the model errors on the cone-beam angle in comparison with the reference models obtained from the optical scanning of the plaster models. For the 3D CT image reconstruction, we used the conventional Feldkamp algorithm and the combined half-scan image reconstruction algorithm to investigate the dependency of the model errors on the image reconstruction algorithm. We analyzed the mean of positive deviations and the mean of negative deviations of the surface points on the CT-image-derived 3D models from the reference model, and we compared them between the two image reconstruction algorithms. It has been found that the model error increases as the cone-beam angle increases in both algorithms. However, the model errors are smaller in the combined half-scan image reconstruction when the cone-beam angle is as large as 10 degrees.

Published
2022
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19. Quantitative susceptibility mapping to evaluate the early stage of Alzheimer's disease

Author

Hyug-Gi Kim, Soonchan Park, Hak Young Rhee, Kyung Mi Lee, Chang-Woo Ryu, Sun Jung Rhee, Soo Yeol Lee, Yi Wang, and Geon-Ho Jahng

Subjects
Computer applications to medicine. Medical informatics, R858-859.7, Neurology. Diseases of the nervous system, RC346-429
Abstract

The objective of this study was to evaluate susceptibility changes caused by iron accumulation in cognitive normal (CN) elderly, those with amnestic mild cognitive impairment (aMCI), and those with early state AD, and to compare the findings with gray matter volume (GMV) changes caused by neuronal loss. The participants included 19 elderly CN, 19 aMCI, and 19 AD subjects. The voxel-based quantitative susceptibility map (QSM) and GMV in the brain were calculated and the differences of those insides were compared among the three groups. The differences of the QSM data and GMVs among the three groups were investigated by voxel-based and region of interest (ROI)-based comparisons using a one-way analysis of covariance (ANCOVA) test with the gender and age as covariates. Finally, a receiver-operating-characteristic (ROC) curve analysis was performed. The voxel-based results showed that QSM demonstrated more areas with significant difference between the CN and AD groups compared to GMV. GMVs were decreased, but QSM values were increased in aMCI and AD groups compared with the CN group. QSM better differentiated aMCI from CN than GMV in the precuneus and allocortex regions. In the accumulation regions of iron and amyloid β, QSM can be used to differentiate between CN and aMCI groups, indicating a useful an auxiliary imaging for early diagnosis of AD. Keywords: Alzheimer's disease (AD), Mild cognitive impairment (MCI), Quantitative susceptibility mapping (QSM), Gray matter volume

Published
2017
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20. Mechanical and Magnetic Properties of the High-Entropy Alloys for Combinatorial Approaches

Author

E-Wen Huang, Guo-Yu Hung, Soo Yeol Lee, Jayant Jain, Kuan-Pang Chang, Jing Jhe Chou, Wen-Chi Yang, and Peter K. Liaw

Subjects
high-entropy alloys, complex concentrated alloys, mechanical behavior, magnetic properties, Crystallography, QD901-999
Abstract

This review summarizes the state of high-entropy alloys and their combinatorial approaches, mainly considering their magnetic applications. Several earlier studies on high-entropy alloy properties, such as magnetic, wear, and corrosion behavior; different forms, such as thin films, nanowires, thermal spray coatings; specific treatments, such as plasma spraying and inclusion effects; and unique applications, such as welding, are summarized. High-entropy alloy systems that were reported for both their mechanical and magnetic properties are compared through the combination of their Young’s modulus, yield strength, remanent induction, and coercive force. Several potential applications requiring both mechanical and magnetic properties are reported.

Published
2020
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21. In Situ Neutron Diffraction Study of Phase Transformation of High Mn Steel with Different Carbon Content

Author

Youngsu Kim, Wookjin Choi, Hahn Choo, Ke An, Ho-Suk Choi, and Soo Yeol Lee

Subjects
high mn steel, phase transformation, carbon, stacking fault energy, neutron diffraction, Crystallography, QD901-999
Abstract

In situ neutron diffraction was employed to examine the phase transformation behavior of high-Mn steels with different carbon contents (0.1, 0.3, and 0.5 wt.%C). With increasing carbon contents from 0.1 C to 0.5 C, the austenite phase fraction among the constituent phases increased from ~66% to ~98%, and stacking fault energy (SFE) increased from ~0.65 to ~16.5 mJ/m2. The 0.1 C and 0.3 C steels underwent phase transformation from γ-austenite to ε-martensite or α’-martensite during tensile deformation. On the other hand, the 0.5 C steel underwent phase transformation only from γ-austenite to ε-martensite. The 0.3 C steel exhibited a low yield strength, a high strain hardening rate, and the smallest elongation. The high strain hardening of the 0.3 C alloy was due to a rapid phase transformation rate from γ-austenite to ε-martensite. The austenite of 0.5 C steel was strengthened by mechanical twinning during loading process, and the twinning-induced plasticity (TWIP) effect resulted in a large ductility. The 0.5 wt.% carbon addition stabilized the austenite phase by delaying the onset of the ε-martensite phase transformation.

Published
2020
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22. Dynamic Strain Evolution around a Crack Tip under Steady- and Overloaded-Fatigue Conditions

Author

Soo Yeol Lee, E-Wen Huang, Wanchuck Woo, Cheol Yoon, Hobyung Chae, and Soon-Gil Yoon

Subjects
fatigue, crack growth, overload, stress/strain, neutron diffraction, Mining engineering. Metallurgy, TN1-997
Abstract

We investigated the evolution of the strain fields around a fatigued crack tip between the steady- and overloaded-fatigue conditions using a nondestructive neutron diffraction technique. The two fatigued compact-tension specimens, with a different fatigue history but an identical applied stress intensity factor range, were used for the direct comparison of the crack tip stress/strain distributions during in situ loading. While strains behind the crack tip in the steady-fatigued specimen are irrelevant to increasing applied load, the strains behind the crack tip in the overloaded-fatigued specimen evolve significantly under loading, leading to a lower driving force of fatigue crack growth. The results reveal the overload retardation mechanism and the correlation between crack tip stress distribution and fatigue crack growth rate.

Published
2015
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23. Study on Compression Induced Contrast in X-ray Mammograms Using Breast Mimicking Phantoms

Author

A. B. M. Aowlad Hossain, Min Hyoung Cho, and Soo Yeol Lee

Subjects
Mammography, Contrast, Breast compression, Tissue elasticity, FEM modeling, Breast phantom, Biology (General), QH301-705.5
Abstract

X-ray mammography is commonly used to scan cancer or tumors in breast using low dose x-rays. But mammograms suffer from low contrast problem. The breast is compressed in mammography to reduce x-ray scattering effects. As tumors are stiffer than normal tissues, they undergo smaller deformation under compression. Therefore, image intensity at tumor region may change less than the background tissues. In this study, we try to find out compression induced contrast from multiple mammographic images of tumorous breast phantoms taken with different compressions. This is an extended work of our previous simulation study with experiment and more analysis. We have used FEM models for synthetic phantom and constructed a phantom using agar and n-propanol for simulation and experiment. The x-ray images of deformed phantoms have been obtained under three compression steps and a non-rigid registration technique has been applied to register these images. It is noticeably observed that the image intensity changes at tumor are less than those at surrounding which induce a detectable contrast. Addition of this compression induced contrast to the simulated and experimental images has improved their original contrast by a factor of about 1.4

Published
2015

24. Twinning-Detwinning Behavior during Cyclic Deformation of Magnesium Alloy

Author

Soo Yeol Lee, Huamiao Wang, and Michael A. Gharghouri

Subjects
magnesium alloy, deformation, twinning, detwinning, neutron diffraction, Mining engineering. Metallurgy, TN1-997
Abstract

In situ neutron diffraction has been used to examine the deformation mechanisms of a precipitation-hardened and extruded Mg-8.5wt.%Al alloy subjected to (i) compression followed by reverse tension (texture T1) and (ii) tension followed by reverse compression (texture T2). Two starting textures are used: (1) as-extruded texture, T1, in which the basal pole of most grains is normal to the extrusion axis and a small portion of grains are oriented with the basal pole parallel to the extrusion axis; (2) a reoriented texture, T2, in which the basal pole of most grains is parallel to the extrusion axis. For texture T1, the onset of extension twinning corresponds well with the macroscopic elastic-plastic transition during the initial compression stage. The non-linear macroscopic stress/strain behavior during unloading after compression is more significant than during unloading after tension. For texture T2, little detwinning occurs after the initial tension stage, but almost all of the twinned volumes are detwinned during loading in reverse compression.

Published
2015
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25. Comparing Cyclic Tension-Compression Effects on CoCrFeMnNi High-Entropy Alloy and Ni-Based Superalloy

Author

Tu-Ngoc Lam, You-Shiun Chou, Yao-Jen Chang, Tsung-Ruei Sui, An-Chou Yeh, Stefanus Harjo, Soo Yeol Lee, Jayant Jain, Bo-Hong Lai, and E-Wen Huang

Subjects
in-situ neutron diffraction, low-cycle fatigue, high entropy alloy, Ni-based superalloy, Crystallography, QD901-999
Abstract

An equal-molar CoCrFeMnNi, face-centered-cubic (fcc) high-entropy alloy (HEA) and a nickel-based superalloy are studied using in situ neutron diffraction experiments. With continuous measurements, the evolution of diffraction peaks is collected for microscopic lattice strain analyses. Cyclic hardening and softening are found in both metallic systems. However, as obtained from the diffraction-peak-width evolution, the underneath deformation mechanisms are quite different. The CoCrFeMnNi HEA exhibits distinct lattice strain and microstructure responses under tension-compression cyclic loadings.

Published
2019
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26. A Ring Artifact Correction Method: Validation by Micro-CT Imaging with Flat-Panel Detectors and a 2D Photon-Counting Detector

Author

Mohamed Elsayed Eldib, Mohamed Hegazy, Yang Ji Mun, Myung Hye Cho, Min Hyoung Cho, and Soo Yeol Lee

Subjects
ring artifact correction, flat-panel detector, photon-counting X-ray detector, correction vector, Gaussian filter, Chemical technology, TP1-1185
Abstract

We introduce an efficient ring artifact correction method for a cone-beam computed tomography (CT). In the first step, we correct the defective pixels whose values are close to zero or saturated in the projection domain. In the second step, we compute the mean value at each detector element along the view angle in the sinogram to obtain the one-dimensional (1D) mean vector, and we then compute the 1D correction vector by taking inverse of the mean vector. We multiply the correction vector with the sinogram row by row over all view angles. In the third step, we apply a Gaussian filter on the difference image between the original CT image and the corrected CT image obtained in the previous step. The filtered difference image is added to the corrected CT image to compensate the possible contrast anomaly that may appear due to the contrast change in the sinogram after removing stripe artifacts. We applied the proposed method to the projection data acquired by two flat-panel detectors (FPDs) and a silicon-based photon-counting X-ray detector (PCXD). Micro-CT imaging experiments of phantoms and a small animal have shown that the proposed method can greatly reduce ring artifacts regardless of detector types. Despite the great reduction of ring artifacts, the proposed method does not compromise the original spatial resolution and contrast.

Published
2017
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27. Energy Calibration of a CdTe Photon Counting Spectral Detector with Consideration of its Non-Convergent Behavior

Author

Jeong Seok Lee, Dong-Goo Kang, Seung Oh Jin, Insoo Kim, and Soo Yeol Lee

Subjects
photon counting spectral detector, spectral x-ray imaging, tube voltage, Medipix-2, CdTe, Chemical technology, TP1-1185
Abstract

Fast and accurate energy calibration of photon counting spectral detectors (PCSDs) is essential for their biomedical applications to identify and characterize bio-components or contrast agents in tissues. Using the x-ray tube voltage as a reference for energy calibration is known to be an efficient method, but there has been no consideration in the energy calibration of non-convergent behavior of PCSDs. We observed that a single pixel mode (SPM) CdTe PCSD based on Medipix-2 shows some non-convergent behaviors in turning off the detector elements when a high enough threshold is applied to the comparator that produces a binary photon count pulse. More specifically, the detector elements are supposed to stop producing photon count pulses once the threshold reaches a point of the highest photon energy determined by the tube voltage. However, as the x-ray exposure time increases, the threshold giving 50% of off pixels also increases without converging to a point. We established a method to take account of the non-convergent behavior in the energy calibration. With the threshold-to-photon energy mapping function established by the proposed method, we could better identify iodine component in a phantom consisting of iodine and other components.

Published
2016
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29. Efficient Intracytoplasmic Labeling of Human Umbilical Cord Blood Mesenchymal Stromal Cells with Ferumoxides

Author

Jae Kwon Lee, Man Kyoung Lee, Hye Jin Jin, Dal-Soo Kim, Yoon Sun Yang, Wonil Oh, Sung-Eun Yang, Tae Seok Park, Soo Yeol Lee, Bum-Soo Kim, and Sin-Soo Jeun

Subjects
Medicine
Abstract

Mesenchymal stromal cells (MSCs) are multipotent cells found in several adult tissues; they have the capacity to differentiate into mesodermal, ectodermal, and endodermal tissues in vitro. There have been several reports that MSCs have therapeutic effects in a variety of diseases. Therefore, using a cell labeling technique, monitoring their temporal and spatial migration in vivo, would be useful in the clinical setting. Magnetic resonance imaging (MRI)—tracking of superparamagnetic iron oxide (SPIO)-labeled cells—is a noninvasive technique for determining the location and migration of transplanted cells. In the present study, we evaluated the influence and toxicity of SPIO (ferumoxides) labeling on multiple differentiated MSCs. To evaluate the influence and toxicity of ferumoxides labeling on differentiation of MSCs, a variety of concentrations of ferumoxides were used for labeling MSCs. We found that the cytoplasm of adherent cells was effectively labeled at low concentrations of ferumoxides. Compared with unlabeled controls, the ferumoxides-labeled MSCs exhibited a similar proliferation rate and apoptotic progression. The labeled MSCs differentiated into osteoblasts and adipocytes in an identical fashion as the unlabeled cells. However, chondrogenesis and neurogenesis were inhibited at high concentrations of ferumoxides. Our results suggest the effective concentration for ferumoxides use in tracking MSCs.

Published
2007
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34. The effects of Y pre-alloying on the in-situ dispersoids of ODS CoCrFeMnNi high-entropy alloy

Author

SeungHyeok Chung, Bin Lee, Changwoo Do, Ho Jin Ryu, and Soo Yeol Lee

Subjects
Materials science, Polymers and Plastics, Zener pinning, Mechanical Engineering, Metals and Alloys, Sintering, Spark plasma sintering, 02 engineering and technology, Atom probe, 010402 general chemistry, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, 0104 chemical sciences, law.invention, Mechanics of Materials, law, Materials Chemistry, Ceramics and Composites, Grain boundary, Composite material, 0210 nano-technology, High-resolution transmission electron microscopy, Electron backscatter diffraction
Abstract

Oxide dispersion strengthened CoCrFeMnNi high-entropy alloys (ODS-HEAs) were prepared using two different powder preparation methods classified by yttrium addition strategy to investigate the effects of in-situ and ex-situ oxide dispersoid formation on the microstructure and mechanical properties. Systematic microstructural analysis was carried out by X-ray diffraction (XRD), electron backscattered diffraction (EBSD), high-resolution transmission electron microscopy (HRTEM), atom probe tomography (APT), and small-angle neutron scattering (SANS). Cryo-milled powder analysis, grain structure evolution after spark plasma sintering, dispersoid characteristics, and matrix/dispersoid interface structure analysis of the in-situ and ex-situ dispersoids within the high-entropy alloy (HEA) matrix were performed. The in-situ dispersoid formation was dominantly observed in the Y-alloyed ODS-HEA through the construction of a coherent interface relationship with complex chemical composition, leading to an increase in the Zener pinning forces on the grain boundary movement. ODS-HEA with in-situ oxide dispersoids enhanced the formation of ultrafine-grained structures with an average diameter of 330 nm at a sintering temperature of 1173 K. This study shows that the Y pre-alloying method is efficient in achieving fine coherent dispersoids with an ultrafine-grained structure, resulting in an enhancement of the tensile strength of the CoCrFeMnNi HEA.

Published
2021

37. Influence of yttrium-induced twinning on the recrystallization behavior of magnesium alloys

Author

Jayant Jain, Soo Yeol Lee, Nooruddin Ansari, and Sudhanshu S. Singh

Subjects
Recrystallization (geology), Materials science, Condensed matter physics, Annealing (metallurgy), Mechanical Engineering, Alloy, chemistry.chemical_element, Yttrium, engineering.material, chemistry, Mechanics of Materials, Content (measure theory), engineering, General Materials Science, Grain boundary, Texture (crystalline), Crystal twinning
Abstract

The present study was designed to investigate the role of $$\left\{ {11\overline{2}1} \right\}$$ extension twinning on deformation and subsequent recrystallization behavior of binary Mg-Y alloys (Mg-5wt.%Y and Mg-10wt.%Y). The selected alloys in solution-treated condition were uniaxially deformed at room temperature and then annealed. Increasing the Y content switches the dominant twinning mode from $$\left\{ {10\overline{1}2} \right\}$$ extension twins and $$\left\{ {10\overline{1}1} \right\} - \left\{ {10\overline{1}2} \right\}$$ double twins, to less commonly observed $$\left\{ {11\overline{2}1} \right\}$$ extension twins. The former was found to assist recrystallization, while the contribution of latter in the formation of new grains was minimal. Moreover, the concurrent precipitation in the Mg-10Y alloy pins the grain boundaries and twin boundaries and thereby suppresses the recrystallization of the alloy despite holding for a longer duration. Finally, the weakening of the annealing texture was only observed in the Mg-5Y alloy as compared to the Mg-10Y alloy. This was attributed to the grain boundary bulging as the prominent mechanism of recrystallization in the Mg-10Y alloy.

Published
2021

42. Enhancement of fatigue resistance by overload-induced deformation twinning in a CoCrFeMnNi high-entropy alloy

Author

Takuro Kawasaki, Yao-Jen Chang, Peter K. Liaw, Ren Fong Cai, Stefanus Harjo, An-Chou Yeh, E-Wen Huang, Ming Jun Li, Soo Yeol Lee, Tu Ngoc Lam, H.S. Chou, Bo Hong Lai, Rui Feng, Sheng Chuan Lo, and Nien-Ti Tsou

Subjects
010302 applied physics, Materials science, Polymers and Plastics, Metals and Alloys, 02 engineering and technology, Paris' law, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Electronic, Optical and Magnetic Materials, Fracture toughness, Residual stress, 0103 physical sciences, Ultimate tensile strength, Ceramics and Composites, Deformation (engineering), Dislocation, Composite material, 0210 nano-technology, Crystal twinning
Abstract

We examined fatigue-crack-growth behaviors of CoCrFeMnNi high-entropy alloys (HEAs) under as-fatigued and tensile-overloaded conditions using neutron-diffraction measurements coupled with diffraction peak-profile analyses. We applied both high-resolution transmission electron microscopy (HRTEM) and neutron-diffraction strain mapping for the complementary microstructure examinations. Immediately after a single tensile overload, the crack-growth-retardation period was obtained by enhancing the fatigue resistance, as compared to the as-fatigued condition. The combined mechanisms of the overload-induced larger plastic deformation, the enlarged compressive residual stresses and plastic-zone size, the crack-tip blunting ahead of the crack tip, and deformation twinning governed the pronounced macroscopic crack-growth-retardation behavior following the tensile overload. A remarkable fracture surface of highly-periodic serrated features along the crack-propagation direction was found in the crack-growth region immediately after the tensile overload. Moreover, a transition of plastic deformation from planar dislocation slip-dominated to twinning-dominated microstructures in the extended plastic zone was clearly observed at room temperature in the overloaded condition, in accordance with the simulated results by a finite element method (FEM). The above tensile overload-induced simultaneously combined effects in the coarse-grained CoCrFeMnNi shed light on the improvement of fatigue resistance for HEAs applications.

Published
2020

44. Integrity Assessment of Obsolete Thermal Storage Tank in District Heating System

Author

Jaehyuk Jang, Daeho Yun, Heesan Kim, Tae Baek Ha, Woo Cheol Kim, Hobyung Chae, Soo Yeol Lee, Jung-Gu Kim, and Joon Cheol Jeong

Subjects
Materials science, Waste management, 020502 materials, 0211 other engineering and technologies, Metals and Alloys, Structural integrity, 02 engineering and technology, Integrity assessment, Thermal energy storage, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Corrosion, Heating system, 0205 materials engineering, Modeling and Simulation, Degradation (geology), 021108 energy
Abstract

The thermal storage tank in a district heating system is a component that stores excess heat during normal operation and releases the stored heat to increase the efficiency of the system, when the heat source is stopped or additional demands occur. Recently, an obsolete thermal storage tank was dismantled for the first time since it began operation 30 years ago. In this work, the corrosion integrity of the obsolete thermal storage tank was evaluated by examining its appearance, thickness thinning, corrosion products, microstructure, and mechanical properties. Samples were taken at various locations (roof, shell, bottom) of the thermal storage tank, which enabled diagnosis of the respective environmental degradations. Severe corrosion was found in the roof edge plate due to corrosion under the insulation, and exhibited thinning exceeding ~49% of the designed thickness. In this location, the ferrite-pearlite band structure disappeared and deteriorated microstructures, such as decarburization and spheroidized pearlite, were measured, which resulted in a ~27% decrease in hardness. The inner surfaces of the bottom and shell plate were well covered with a magnetite film, and the degradation of the microstructure and mechanical properties showed a permissible limit in terms of ASTM A285/A516. In addition, no particular drop in hardness was found in the weld zone of each plate.

Published
2020

45. Phase Stress Partition in Gray Cast Iron Using In Situ Neutron Diffraction Measurements

Author

Szu-Chien Wu, Shi-Wei Chen, Jayant Jain, Tu-Ngoc Lam, Hobyung Chae, E-Wen Huang, Ke An, Sven C. Vogel, Soo Yeol Lee, Dunji Yu, and Sung-Mao Chiu

Subjects
010302 applied physics, Austenite, Materials science, Structural material, Neutron diffraction, Metallurgy, 0211 other engineering and technologies, Metals and Alloys, 02 engineering and technology, engineering.material, Condensed Matter Physics, 01 natural sciences, Mechanics of Materials, Residual stress, 0103 physical sciences, engineering, Gray iron, Graphite, Cast iron, Deformation (engineering), Composite material, 021102 mining & metallurgy
Abstract

Gray cast iron comprises α-Fe, Fe3C and graphite with their different anisotropies in terms of structure and mechanical behavior. We perform two different deformation paths as tension-compression and compression-tension on bulk gray iron to capture the stress partitioning. Using in situ neutron diffraction, the composite-like deformation behaviors of α-Fe and Fe3C are revealed simultaneously. Within the elastic deformation stage, both deformation paths do not cause load transfer. However, when the applied compressive stress exceeds 300 MPa, there is a clear load sharing in both paths. From microscopic examinations, the debonding between matrix and graphite is clarified.

Published
2020

46. Evaluation of Icephobic and Dissipation Performance on Coating Materials for Preventing Overhead Transmission Line from Ice/Snow Damages

Author

You Sub Kim, Hui Jae Cho, Seungtae Oh, Hyongjoon Lee, Youngsuk Nam, Jaehwan Shim, Sang Chul Han, Song Ho Sohn, Yong Chan Jung, and Soo Yeol Lee

Subjects
Materials science, Polymers and Plastics, Traditional medicine, General Chemical Engineering, Materials Chemistry
Abstract

본 연구에서는 송전선 결빙으로 인한 피해를 최소화하고자 상온 경화형 실리콘 고무에 입자 크기와 혼합 배열을 달리한 알루미늄 안료를 첨가하여 결빙 방지 코팅재를 제조하였다. 접촉각과 표면에너지 측정을 통해 표면 거칠기가 높은 코팅재가 뛰어난 발수성을 가짐을 확인하였다. 하지만, 결빙 방지 성능은 표면 거칠기와 경도가 낮을수록 우수하였다. 연속허용전류 인가 실험 결과, 실리콘 고무 코팅재의 방열성능이 가장 우수하였으며, 이는 실리콘고무의 복사율이 가장 컸기 때문이다. 또한 가속 열화 시험과 얼음 탈착/부착 반복 시험을 통하여 실리콘 고무 코팅재는 장기간 물성 변화 없이 우수한 결빙 방지 성능이 유지됨을 알 수 있었다. 본 연구를 통하여 개발된 코팅재는 송전선의 결빙 방지를 위해 충분히 사용될 수 있는 가능성을 보여주었으며, 특히 우수한 방열특성으로 인하여 송전선의 온도도 낮추어 주기 때문에 여름철 전력 효율을 높이는데도 크게 기여를 할 수 있을 것으로 생각된다.

Published
2020

47. A new contour method for rapid evaluation of the cross-sectional residual stress distribution in complex geometries using a 3D scanner

Author

Huai Wang, Wanchuck Woo, Dong-Kyu Kim, Sun Kwang Hwang, Shi-Hoon Choi, and Soo Yeol Lee

Subjects
0209 industrial biotechnology, Scanner, Materials science, Mechanical Engineering, Acoustics, 02 engineering and technology, Welding, law.invention, Stress (mechanics), 020303 mechanical engineering & transports, 020901 industrial engineering & automation, Distribution (mathematics), 0203 mechanical engineering, Mechanics of Materials, law, Residual stress, Range (statistics), Noisy data, Uncertainty analysis
Abstract

This paper presents a new method for contour measurements using a 3D scanner to determine cross-sectional residual stresses in structural components with complex configurations. The proposed method was applied to evaluate the axial residual stress distribution in a dissimilar pipe weld and the obtained results were compared with those obtained using a benchmarked contour measurement machine (CMM) equipped with a confocal laser probe for verification. It reveals a quantitative agreement between the two methods in terms of both the measured contours and the calculated residual stresses. Most importantly, this method allows a significantly reduced measurement time by ≈99 % (≈20 min, with an effective measurement speed of ≈0.2 sec/mm2), compared to the benchmarked method (≈48 hr, with an effective measurement speed of ≈28.7 sec/mm2). Based on stress uncertainty analysis, this method guarantees a longer range of stable fits due to fewer noisy data points than the benchmarked method.

Published
2020

48. Transient Phase-Driven Cyclic Deformation in Additively Manufactured 15-5 PH Steel

Author

Tu-Ngoc Lam, Yu-Hao Wu, Chia-Jou Liu, Hobyung Chae, Soo-Yeol Lee, Jayant Jain, Ke An, and E-Wen Huang

Subjects
Technology, Microscopy, QC120-168.85, 15-5 PH stainless steel, QH201-278.5, martensite transformation, Engineering (General). Civil engineering (General), TK1-9971, Descriptive and experimental mechanics, selective laser melting, low-cycle fatigue, General Materials Science, in-situ neutron diffraction, Electrical engineering. Electronics. Nuclear engineering, TA1-2040
Abstract

The present work extends the examination of selective laser melting (SLM)-fabricated 15-5 PH steel with the 8%-transient-austenite-phase towards fully-reversed strain-controlled low-cycle fatigue (LCF) test. The cyclic-deformation response and microstructural evolution were investigated via in-situ neutron-diffraction measurements. The transient-austenite-phase rapidly transformed into the martensite phase in the initial cyclic-hardening stage, followed by an almost complete martensitic transformation in the cyclic-softening and steady stage. The compressive stress was much greater than the tensile stress at the same strain amplitude. The enhanced martensitic transformation associated with lower dislocation densities under compression predominantly governed such a striking tension-compression asymmetry in the SLM-built 15-5 PH.

Published
2022

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