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The nano Single crystal gamma - TiAl alloy strain rate effect of molecular dynamics simulation
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College of Mechano-Electronical Engineering,Lanzhou Univ of Tech,College of Mechano-Electronical Engineering,Lanzhou Univ of Tech,Lanzhou institute of industrial,Lanzhou Univ of Tech,College of Mechano-Electronical Engineering,Lanzhou Univ of Tech,College of Mechano-Electronical Engineering,Lanzhou Univ of Tech

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TG146.23; O346.1

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    Abstract:

    The propagation form of the preset edge crack in The nano Single crystal gamma-TiAl under different strain rate were simulated by the method of molecular dynamics in this paper, velocity loading way was used to obtain dynamic uniaxial tensile for preset edge crack in the single crystal gamma-TiAl within 5.0*107S-1~7.5*109 S-1. The results showed that the crack propagation form varies with the range of strain rate. In the non-sensitive region(≤4*108 S-1), the crack propagates in a brittle cleavage manner. In the sensitive region(4.0*108 S-1<the strain≤1.0*109 S-1), it was cleavage extension features Early,the slip dislocation was emitted from the crack tip, and the void defect initiates the place where dislocation piled up and then growed to the child crack later,the child crack linked the main crack when it biased 45-degree under the strain≤5.0*108 S-1,but it connected the main crack at the same direction under 5.0*108 S-1<the strain≤1.0*109 S-1,thus leaded to the fracture both finally; In the sharp-change region(≥1.0*109 S-1), the crack didnt craze in the maximum stress for the reinforcement of strain,and the Stress decreased for it continues to increase some time. The non-crystallizing of the atom structure occurs near the crack tip because of high strain rate, and then the micro crack initiates in area of structure disordered, the micro crack growth leads to the “test specimen” fracture eventually.

    Reference
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[LUO De-chun, FU Rong, Zhang ling, CAO Hui, RUI Zhi-yuan. The nano Single crystal gamma - TiAl alloy strain rate effect of molecular dynamics simulation[J]. Rare Metal Materials and Engineering,2018,47(3):853~859.]
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History
  • Received:January 14,2016
  • Revised:May 03,2016
  • Adopted:May 18,2016
  • Online: April 11,2018