Abstract <p>Recent research has shown that zinc alloys are among the most promising materials for bioresorbable (biosoluble) implants. This paper presents the phase transformation of a new promising bioresorbable alloy, Zn–0.8Li. It was found that after quenching from 300°C, the alloy has a structure consisting of a mixture of two isomorphic supersaturated solid solutions: a Li solution in the zinc phase and a Zn solution in the primary crystallites of the LiZn<sub>4</sub> phase. During subsequent aging for 20–50 h at room temperature, the alloy undergoes natural aging, during which thin (approximately 1 μm thick) zinc plates precipitate in the LiZn<sub>4</sub> phase, and submicron LiZn<sub>4</sub> particles precipitate in the zinc phase. The phase transformation pattern during aging was obtained based on the results of X-ray diffraction analysis, SEM microstructural studies, and electrical conductivity studies at different stages of natural aging. The maximum microhardness value is achieved after 48 h of aging.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Kinetics of Phase Transformations in the Zn–0.8% Li Alloy

  • O. B. Kulyasova,
  • V. V. Astanin,
  • R. F. Almukhametov,
  • A. R. Khasanova,
  • Dandan Xia,
  • Yufeng Zheng

摘要

Abstract

Recent research has shown that zinc alloys are among the most promising materials for bioresorbable (biosoluble) implants. This paper presents the phase transformation of a new promising bioresorbable alloy, Zn–0.8Li. It was found that after quenching from 300°C, the alloy has a structure consisting of a mixture of two isomorphic supersaturated solid solutions: a Li solution in the zinc phase and a Zn solution in the primary crystallites of the LiZn4 phase. During subsequent aging for 20–50 h at room temperature, the alloy undergoes natural aging, during which thin (approximately 1 μm thick) zinc plates precipitate in the LiZn4 phase, and submicron LiZn4 particles precipitate in the zinc phase. The phase transformation pattern during aging was obtained based on the results of X-ray diffraction analysis, SEM microstructural studies, and electrical conductivity studies at different stages of natural aging. The maximum microhardness value is achieved after 48 h of aging.