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Johnson, W. C.; Lee, J. K. |
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Publication |
The Elastic Field of an Inhomogeneous System |
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Book Chapter |
Pages |
1982 |
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Abstract |
Solid-State Phase Transformations |
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Summary Language |
151-155 |
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The Metallurgical Society of AIME |
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Warrendale |
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Aaronson, H. I.; Laughlin, D. E.; Sekerka, R. F.; Wayman, C. M. |
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W.C. Johnson and J.K. Lee, "The elastic field of an inhomogeneous system," in Proc. Internat. Conf. on Solid-solid Phase Transformations, eds. H.I. Aaronson, D.E. Laughlin, R.F. Sekerka, and G.M. Wayman (TMS-AIME, 1982) pp. 151-155. |
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refbase @ user |
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1253 |
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Lee, J. K.; Johnson, W. C. |
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Influence of Transformation Strain Energy Upon Diffusional Nucleation and Growth |
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Book Chapter |
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1982 |
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Solid-State Phase Transformations |
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127-150 |
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The Metallurgical Society of AIME |
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Warrendale |
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Aaronson, H. I.; Laughlin, D. E.; Sekerka, R. F.; Wayman, C. M. |
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W.C. Johnson and J.K. Lee, "The elastic field of an inhomogeneous system," in Proc. Internat. Conf. on Solid-solid Phase Transformations, eds. H.I. Aaronson, D.E. Laughlin, R.F. Sekerka, and G.M. Wayman (TMS-AIME, 1982) pp. 151-155. |
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refbase @ user |
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1331 |
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Legoues, F. K.; Aaronson, H. I.; Lee, Y. W.; Fix, G. J. |
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Influence of Crystallography Upon Critical Nucleus Shapes and Kinetics of Homogeneous FCC-FCC Nucleation--Part I. The Classical Theory Regime |
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Book Chapter |
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1982 |
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Solid-State Phase Transformations |
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427-431 |
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The Metallurgical Society of AIME |
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Warrendale |
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Aaronson, H. I.; Laughlin, D. E.; Sekerka, R. F.; Wayman, C. M. |
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W.C. Johnson and J.K. Lee, "The elastic field of an inhomogeneous system," in Proc. Internat. Conf. on Solid-solid Phase Transformations, eds. H.I. Aaronson, D.E. Laughlin, R.F. Sekerka, and G.M. Wayman (TMS-AIME, 1982) pp. 151-155. |
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refbase @ user |
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1339 |
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Cade, J. N. A., S E; Lee, R. A. |
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Fabrication of sharp field emission structures using ion beam milling |
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Book Chapter |
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1990 |
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Vacuum Microelectronics, 1989 |
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5-8 |
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Field Emission |
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Institute of Physics |
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Bristol |
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Turner, Roy E. |
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0854980555 |
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4823 |
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Lee, R. A.; Miller, A. J.; Patel, C.; Williams, H. A. |
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Construction and performance of field emitting cathodes |
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Book Chapter |
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1990 |
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Vacuum Microelectronics, 1989 |
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105-108 |
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Field Emission |
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Institute of Physics |
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Bristol |
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Turner, Roy E. |
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4839 |
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Sinnott, Susan; Mao, Zugang; Lee, Kiho |
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Computational Studies of Molecular Diffusions through Carbon Nanotubes Based membrances (Invited) |
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Journal Article |
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2002 |
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Computer Modeling in Engineering and Science |
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575-587 |
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Nanofluidics is an area that has been under study for some time in zeolites and idea nanoporous systems. Computational studies of the behavior of molecules in nanoporous structures have played an important role in understanding this phenomenon as experimental studies of molecular behavior in nanometer-scale pores are difficult to perform. in this paper computational work to study molecular motion and the separation of molecular mixtures in carbon nanotube systems is reported. The systems examined include organic molecules, such as CH4, C2H6, n-C4H10, and i-c4H10, and inorganic molecules, such as CO2. The interatomic forces in the molecular dynamics simulations are calculated using a classical reactive empirical bond order hydrocarbon potetial coupled to lernard-Jones and coulombic potentials. Molecules moving at thermal velocities corresponding to 300K are predicted to diffuse from areas of high density to areas of low density through the nanotubes. The simulations indicate how the structure and size of molecules and the nanotubes influence molecular diffusion through the nanotubes and the separation of the molecular mixtures. |
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NU @ z-mao2 @ |
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198 |
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Ahmad, Zaki; Ul-Hamid, Anwar; B.J., Abdul-Aleem |
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The corrosion behavior of scandium alloyed Al 5052 in neutral sodium chloride solution |
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Journal Article |
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2001 |
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Corrosion Science |
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43 |
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1227-1243 |
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Corrosion; Al–Mg–Sc; Age-hardening; Microstructure; Pitting potential; Polarization |
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Alloying with scandium has a strong influence on the strengthening and weight saving characteristics of Al–2.5Mg alloys. Scandium addition (0.1–0.3 wt.%) to Al–2.5Mg alloys does not introduce any appreciable loss in their resistance to corrosion in 3.5 wt.% NaCl. The corrosion behavior of these alloys is not significantly affected by age hardening. Because of a unique combination of outstanding mechanical properties and a good resistance to corrosion Al–Mg alloys containing scandium represent a major improvement over the more familiar Al–Mg alloys. |
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NU @ karnesky @ |
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435 |
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Park, Kyung-Tae; Hwang, Duck-Young; Lee, Young-Kook; Kim, Young-Kuk; Shin, Dong Hyuk |
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High strain rate superplasticity of submicrometer grained 5083 Al alloy containing scandium fabricated by severe plastic deformation |
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Journal Article |
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2003 |
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Materials Science and Engineering A |
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Mater. Sci. Eng. A |
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341 |
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1-2 |
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273-281 |
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High strain rate superplasticity; 5083 Al alloy; Scandium; Severe plastic deformation; Ultrafine grains |
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High strain rate superplasticity (HSRS) was obtained in a commercial 5083 Al alloy by introducing a ultrafine grained structure of 0.3 small mu, Greekm through severe plastic deformation and by adding a dilute amount of scandium (Sc) as a microstructure stabilizer. Tensile tests were carried out on the as-processed sample at temperatures of 623–823 K and initial strain rates of 1×10−3–1×100 s−1. The maximum elongation to failure of 740% was obtained at 773 K and 1×10−2 s−1. HSRS of the alloy was attributed to the combined effects of dynamic recrystallization and preservation of fine recrystallized grains by the presence of Sc. The mechanical behavior of the alloy at 773 K was characterized by a sigmoidal behavior in a plot of stress vs strain rate in the double logarithmic scale. The origin of the sigmoidal behavior was discussed in terms of microstructural evolution during superplastic deformation. An examination of the fractured samples revealed that failure occurred in a brittle manner related to cavitation rather than necking. Cavity stringers were formed parallel to the tensile axis by interlinkage of jagged-shaped isolated cavities along grain boundaries aligned to the tensile axis. |
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NU @ karnesky @ |
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585 |
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Park, Kyung-Tae; Lee, Hang-Jae; Lee, Chong Soo; Nam, Won Jong; Shin, Dong Hyuk |
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Enhancement of high strain rate superplastic elongation of a modified 5154 Al by subsequent rolling after equal channel angular pressing |
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Journal Article |
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2004 |
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Scripta Materialia |
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Scripta Mater. |
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51 |
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6 |
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479-483 |
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Aluminum alloy; Superplasticity; Equal channel angular pressing; Rolling |
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Subsequent rolling after equal channel angular pressing (ECAP) resulted in a considerable enhancement of the high strain rate superplastic elongation of a modified 5154 Al alloy, compared to that of the alloy subjected to the identical ECAP strain without rolling. The mechanical data revealed that the deformation of the former was governed by grain boundary sliding but that of the latter was dominated by viscous glide. |
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NU @ karnesky @ |
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586 |
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Suh,Dong-Woo; Lee, Sang-Yong; Lee, Kyong-Hwan; Lim, Su-Keun; Oh, Kyu Hwan |
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Microstructural evolution of Al–Zn–Mg–Cu–(Sc) alloy during hot extrusion and heat treatments |
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Journal Article |
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2004 |
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Journal of Materials Processing Technology |
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155-156 |
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1330-1336 |
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Scandium; Microstructure; Recovery; Recrystallization |
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The microstructural evolution during hot extrusion and post heat treatment was investigated for two kind of Al–Zn–Mg–Cu–(Sc) alloy and AA7075. The microstructure of as-extruded bar is mainly comprised of recovered structure for all alloys, however, different restoration processes are observed during post heat treatment. For AA7075 and S1, which contains 0.1% Sc with relatively higher Zn and Cu content than S2, recovery still proceeds during the heat treatment, while the recrystallization becomes main restoration process during the heat treatment for S2.
The differences in abnormal grain growth and hardening behavior between S1, AA7075 and S2 during the heat treatment are discussed in connection with the restoration processes and resultant microstructures. |
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NU @ karnesky @ |
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622 |
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