<p>Brief heat treatments offer an energy-efficient method for adjusting the microstructure and properties of Nitinol; however, the microstructural mechanisms that occur during the early stages of these treatments remain largely unrecorded. In this study, a hot-rolled superelastic sheet was annealed for 60&#xa0;s at temperatures of 520°C, 540°C, 560°C, 580°C, and 600°C. After annealing, the samples were analyzed using transmission electron microscopy, electron backscatter diffraction, x-ray diffraction, and differential scanning calorimetry. After a 1-min heat treatment at 520–600°C, the dislocation density drops by three orders of magnitude. The texture shifts from a rolling α-fiber (&lt;110&gt;|| RD) to a γ-rich state ({111} || ND) with increasing {001}. At 520°C, the change is mostly recovery; by 560°C, orientation near {111}&lt;112&gt; dominates; at 580–600°C, growth/coarsening broadens the γ fiber and partially de-textures the sheet. Simultaneously, defect-assisted precipitation of coherent Ni<sub>4</sub>Ti<sub>3</sub> plates preserved the recovered texture and stabilized a multi-step transformation. Quantitative correlations among recovery, texture retention, and nanoscale precipitation were established, demonstrating that a 1-min treatment at moderate temperatures can achieve fine grains and minimal defect content. The study offers a commercially viable method for rapid, customizable post-processing of NiTi components.</p>

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Impact of Short-Term Annealing on Microstructure and Transformation Temperatures of Hot-Rolled Superelastic Nitinol

  • Seyed Aref Golsorkhi,
  • Melodie Fickenscher,
  • Le Zhou,
  • Dinc Erdeniz

摘要

Brief heat treatments offer an energy-efficient method for adjusting the microstructure and properties of Nitinol; however, the microstructural mechanisms that occur during the early stages of these treatments remain largely unrecorded. In this study, a hot-rolled superelastic sheet was annealed for 60 s at temperatures of 520°C, 540°C, 560°C, 580°C, and 600°C. After annealing, the samples were analyzed using transmission electron microscopy, electron backscatter diffraction, x-ray diffraction, and differential scanning calorimetry. After a 1-min heat treatment at 520–600°C, the dislocation density drops by three orders of magnitude. The texture shifts from a rolling α-fiber (<110>|| RD) to a γ-rich state ({111} || ND) with increasing {001}. At 520°C, the change is mostly recovery; by 560°C, orientation near {111}<112> dominates; at 580–600°C, growth/coarsening broadens the γ fiber and partially de-textures the sheet. Simultaneously, defect-assisted precipitation of coherent Ni4Ti3 plates preserved the recovered texture and stabilized a multi-step transformation. Quantitative correlations among recovery, texture retention, and nanoscale precipitation were established, demonstrating that a 1-min treatment at moderate temperatures can achieve fine grains and minimal defect content. The study offers a commercially viable method for rapid, customizable post-processing of NiTi components.