Phase-Structural State of τ-MnAl(Ga) Alloys Prepared at Different Cooling Rates

IF 1.1 4区材料科学 Q3 METALLURGY & METALLURGICAL ENGINEERING

Physics of Metals and Metallography Pub Date : 2024-08-09 DOI:10.1134/s0031918x24600374

A. S. Fortuna, N. M. Vazhinskii, K. S. Nechaev, T. A. Morozova, M. V. Gorshenkov, D. Yu. Karpenkov, E. S. Malyutina

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Abstract

An alloy with a nominal composition of Mn₅₅Al₃₆Ga₉ is prepared by four different methods which ensure different cooling rates. Two bulk samples are prepared by induction melting followed by water quenching from a homogenizing temperature of 1100ºС; one of the samples was sealed in a quartz ampoule and subjected to water quenching, whereas the other sample directly was subjected to water quenching. Two samples are prepared in the form of ribbons by quenching from the melt on a rotating copper wheel at linear speeds of 10 and 40 m/s. Thus, samples quenched at different rates are prepared. For these samples, regularities of phase transitions occurred during heating are determined, and difference in the regularities for the bulk and rapidly quenched samples are found. Based on the data obtained, we make an assumption that the γ₂ → τ phase transition has features of a bulk transition. Magnetic hysteretic properties of the rapidly quenched ribbons are measured. The high thermal stability of the rapidly quenched ribbons alloyed with gallium is shown.

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以不同冷却速率制备的τ-锰铝(镓)合金的相结构状态

一种标称成分为 Mn55Al36Ga9 的合金通过四种不同的方法制备，这些方法可确保不同的冷却速度。其中一个样品密封在石英安瓿瓶中，然后进行水淬，而另一个样品则直接进行水淬。通过在线速度分别为 10 米/秒和 40 米/秒的旋转铜轮上从熔体中淬火，制备出两种带状样品。这样就制备出了以不同速度淬火的样品。对于这些样品，我们测定了加热过程中发生的相变的规律性，并发现了块状样品和快速淬火样品的规律性差异。根据所获得的数据，我们推测 γ2 → τ 相变具有块体转变的特征。测量了快速淬火带的磁滞特性。结果表明，与镓合金化的快速淬火带具有很高的热稳定性。

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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来源期刊

Physics of Metals and Metallography 工程技术-冶金工程

CiteScore

2.00

自引率

25.00%

发文量

108

审稿时长

3 months

期刊介绍： The Physics of Metals and Metallography (Fizika metallov i metallovedenie) was founded in 1955 by the USSR Academy of Sciences. Its scientific profile involves the theory of metals and metal alloys, their electrical and magnetic properties, as well as their structure, phase transformations, and principal mechanical properties. The journal also publishes scientific reviews and papers written by experts involved in fundamental, application, and technological studies. The annual volume of publications amounts to some 250 papers submitted from 100 leading national scientific institutions.