Molecular Dynamics Simulation of Tensile Deformation of Iron Single Crystals Including Thermal Effect
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概要
- 論文の詳細を見る
The ductile-brittle transition of α-iron single crystals under a constant tensile stress is simulated by a molecular dynamics approach, focusing on thermal distribution in the crystals, where the Newton equations of motion are solved utilizing the Johnson potential. The simulation uses the ad-hoc velocity scaling method to control the crystal deformation at a low temperature, and showed brittle fracture starting at a notch in the plane perpendicular to the direction of stress. Another simulation where no scaling was used, and hence the temperature of the crystal increased during the deformation, showed plastic deformation at slip planes. From these two simulations, the brittle-to-ductile transition of α-iron can be explained by the temperature effect under deformation. With the use of a definition for local temperature at a nonequilibrium state, a substantial temperature increase was observed near the crack.
- 社団法人日本機械学会の論文
- 1993-01-15
著者
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SASAKI Naoya
Mechanical Engineering Research Laboratory, Hitachi, Ltd.
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Iwasaki T
Hitachi Ltd. Ibaraki Jpn
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Iwasaki Tomio
Mechanical Engineering Res. Lab. Hitachi Ltd.
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CHIBA Norimasa
Mechanical Engineering Research Laboratory, Hitachi Ltd.
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Abe Yasuo
Mechanical Engineering Research Laboratory, Hitachi Ltd.
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Ishikawa Yuichi
Mechanical Engineering Research Laboratory, Hitachi, Ltd.
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Chiba Norimasa
Mechanical Engineering Research Laboratory Hitachi Ltd.
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Chiba Norimasa
Mechanical Engineering Lab. Hitachi Ltd.
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Yasukawa A
Hokkaido Univ. Sapporo Jpn
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Ishikawa Yuichi
Mechanical Engineering Laboratory Agency Of Industrial Science And Technology Ministry Of Internatio
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Ishikawa Yuichi
Mechanical Engineering Research Laboratory Hitachi Ltd.
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Sasaki N
Hitachi Ltd. Ibaraki Jpn
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Sasaki Naoya
Mechanical Engineering Research Laboratory Hitachi Ltd.
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IWASAKI Tomio
Mechanical Eng. Res. Laboratory, Hitachi, Ltd.
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