退火诱导的超细晶Al和Al- mg合金晶粒细化和硬化

Materials Engineering eJournal Pub Date : 2021-01-01 DOI:10.2139/ssrn.3881876

Dengshan Zhou, Yifan Bu, O. Muránsky, H. Geng, Binhan Sun, Chao Yang, Deliang Zhang

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摘要

本研究表明，在超细晶Al和Al-(2.5、5和7.5)中含有亚晶的拉长晶粒。通过机械合金化和快速粉末固结制备的Mg样品在随后的退火过程中再结晶形成更细的等轴基体晶粒。退火也促进了纳米级氧化物颗粒的形成。高数量密度的氧化纳米粒子和细小的再结晶晶粒保证了退火样品的高热稳定性和增强的强度，同时保持了它们在挤压状态下的良好延展性。本实验结果为开发具有高强度和良好延展性的高热稳定性超细晶Al-Mg基合金提供了一条令人兴奋的途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Annealing-Induced Grain Refinement and Hardening in Ultrafine-Grained Al and Al-Mg Alloys

This work shows that the elongated grains that contain subgrains in bulk ultrafine-grained Al and Al-(2.5, 5 and 7.5)at.%Mg samples, fabricated by mechanical alloying and rapid powder consolidation, recrystallize to develop finer equiaxed matrix grains during subsequent annealing. The annealing also promotes formation of nanoscale oxide particles. The high number density oxide nanoparticles and fine recrystallized grains warrant high thermal stability and enhanced strength of the annealed samples while maintaining the good ductility of their as-extruded counterparts. The present experimental findings offer an exciting pathway in developing high thermal stability ultrafine-grained Al-Mg based alloys with a notable combination of high strength and good ductility.

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Materials Engineering eJournal

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