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静态高压下锆的相变及ω-Zr相在高温下的稳定性

Zirconium Phase Transformation under Static High Pressure and ω-Zr Phase Stability at High Temperatures.

作者信息

Jaworska Lucyna, Cyboron Jolanta, Cygan Slawomir, Zwolinski Adam, Onderka Boguslaw, Skrzekut Tomasz

机构信息

Faculty of Non-Ferrous Metals, AGH University of Science and Technology, A. Mickiewicza Av. 30, 30-059 Krakow, Poland.

Lukasiewicz Research Network-Institute of Advanced Manufacturing Technology, Wroclawska St. 37a, 30-011 Krakow, Poland.

出版信息

Materials (Basel). 2019 Jul 12;12(14):2244. doi: 10.3390/ma12142244.

DOI:10.3390/ma12142244
PMID:31336839
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6678209/
Abstract

High-purity Zr has been observed to undergo a phase transformation from the α-phase to the hexagonal ω-phase under high pressure generated either statically or by shock loading. The transition pressure from α-Zr to ω-Zr at 300 K is 2.10 GPa. The main aim of this research was to determine the conditions of α-Zr in ω-Zr transformation and the state of stresses after the high-pressure pressing and sintering of zirconium powders. Commercially acquired zirconium powders of 99.9% and 98.8% purity were used in this study. Qualitative and quantitative phase analysis of the materials was carried out using X-ray diffraction. The materials were statically pressed and sintered using a Bridgman-type toroidal apparatus at under 4.0 and 7.8 GPa. After pressing, the transformation proceeded for the zirconium powder containing 98.8% purity (with hydrides admixture) but did not occur for the high-purity zirconium powders with 99.9% purity. The zirconium powders were sintered using the HPHT (High Pressure-High Temperature) method at temperatures of 1273 K and 1473 K. The transformation proceeded for both powders. The highest contribution of the ω-Zr phase was obtained in the zirconium (98.8% purity with the hydrides contents) sintered for 1 min at a temperature of 1473 K and a pressure of 7.8. The ω-phase content was 87 wt.%. The stress measurement was performed for the pressed and sintered materials using the sinψ X-ray diffraction method. The higher sintering temperature resulted in a decrease of the residual stresses in the ω-Zr phase for the sintered zirconium. The higher levels of stress limited the transformation of the α-Zr phase into the ω-Zr phase. Investigated materials characterized by higher compressive macrostresses were also typical of the greater stability of the ω-Zr phase at high temperatures.

摘要

据观察,高纯度锆在静态或冲击加载产生的高压下会经历从α相到六方ω相的相变。在300 K时,从α-Zr到ω-Zr的转变压力为2.10 GPa。本研究的主要目的是确定锆粉在高压压制和烧结后α-Zr向ω-Zr转变的条件以及应力状态。本研究使用了商业采购的纯度为99.9%和98.8%的锆粉。使用X射线衍射对材料进行了定性和定量相分析。使用布里奇曼型环形装置在4.0和7.8 GPa以下对材料进行静态压制和烧结。压制后,纯度为98.8%(含氢化物混合物)的锆粉发生了转变,但纯度为99.9%的高纯度锆粉未发生转变。使用高温高压(HPHT)方法在1273 K和1473 K的温度下对锆粉进行烧结。两种粉末都发生了转变。在1473 K温度和7.8压力下烧结1分钟的锆(纯度98.8%,含氢化物)中,ω-Zr相的贡献最大。ω相含量为87 wt.%。使用sinψ X射线衍射方法对压制和烧结后的材料进行应力测量。较高的烧结温度导致烧结锆中ω-Zr相的残余应力降低。较高水平的应力限制了α-Zr相向ω-Zr相的转变。具有较高压缩宏观应力特征的研究材料在高温下ω-Zr相也具有更大的稳定性。

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本文引用的文献

1
Anisotropic kinetics of solid phase transition from first principles: alpha-omega phase transformation of Zr.
Phys Chem Chem Phys. 2016 Feb 14;18(6):4527-34. doi: 10.1039/c5cp07299a.
2
High Pressure Phase-Transformation Induced Texture Evolution and Strengthening in Zirconium Metal: Experiment and Modeling.锆金属中高压相变诱导的织构演变与强化:实验与建模
Sci Rep. 2015 Jul 28;5:12552. doi: 10.1038/srep12552.
3
Crystal Structures of Titanium, Zirconium, and Hafnium at High Pressures.钛、锆和铪在高压下的晶体结构。
Zr-Nb粉末混合物的压力压实以及烧结和KOBO挤压Zr-xNb材料的选定性能
Materials (Basel). 2021 Jun 9;14(12):3172. doi: 10.3390/ma14123172.
Science. 1963 Apr 5;140(3562):72-3. doi: 10.1126/science.140.3562.72.
4
Temperature dependence of the omega -bcc phase transition in zirconium metal.锆金属中ω体心立方相变的温度依赖性。
Phys Rev B Condens Matter. 1991 Nov 1;44(18):10374-10376. doi: 10.1103/physrevb.44.10374.