M. V. Gorshenkov, N. M. Vazhinskii, K. S. Nechaev, T. A. Morozova
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引用次数: 0
摘要
采用电弧熔炼法制备了成分为Mn58.5Al31.8Ga9.7和Mn58.3Al34Ga7.7的掺ga Mn-Al合金,并成功转变为铁磁L1.0相。两种合金完全转变的途径不同。对于7.7 at % Ga合金,以中等速率进行单步冷却足以使其转变为L1.0相。相比之下,9.7 at % Ga合金需要在550℃下额外退火2小时才能完成向所需的L1.0组织的转变。在第二种情况下,L1.0相由两种不同的铁磁性L1.0组分组成,居里温度分别为Tc1 = 302℃和Tc2 = 362℃,它们由不同的ε和γ2相演化而来,在1100℃时稳定存在。利用电子背散射衍射(EBSD)研究了γ - 2→τ相的转变,发现τ(γ - 2)相从界面处开始转变,并继承了界面处τ(ε)相的取向,而两相的化学成分基本保持不变。
Two L1.0 Phases Formation in Mn–Al–Ga Alloy with Different Ga Content
Ga-doped Mn–Al alloys with compositions of Mn58.5Al31.8Ga9.7 and Mn58.3Al34Ga7.7 were produced by arc melting and subsequently successfully transformed into the ferromagnetic L1.0 phase. The pathways of complete transformations differed for the two alloys. For the 7.7 at % Ga alloy, a single-step cooling process at an intermediate rate was sufficient to transform it into the L1.0 phase. In contrast, the 9.7 at % Ga alloy required an additional annealing step at 550°C for 2 h to complete the transformation to the desired L1.0 structure. In second case the L1.0 phase consists of two distinct ferromagnetic L1.0 components with Curie temperatures of Tc1 = 302°C and Tc2 = 362°C, which evolved from different initial ε and γ2 phases that were stable at 1100°C. The transformation of the γ2 → τ phase was studied using electron back-scatter diffraction (EBSD), revealing that the τ(γ2) phase began transforming from the interface and inherited the orientation of the τ(ε) phase at the interface, while the chemical compositions of both phases remained almost constant.
期刊介绍:
Bulletin of the Russian Academy of Sciences: Physics is an international peer reviewed journal published with the participation of the Russian Academy of Sciences. It presents full-text articles (regular, letters to the editor, reviews) with the most recent results in miscellaneous fields of physics and astronomy: nuclear physics, cosmic rays, condensed matter physics, plasma physics, optics and photonics, nanotechnologies, solar and astrophysics, physical applications in material sciences, life sciences, etc. Bulletin of the Russian Academy of Sciences: Physics focuses on the most relevant multidisciplinary topics in natural sciences, both fundamental and applied. Manuscripts can be submitted in Russian and English languages and are subject to peer review. Accepted articles are usually combined in thematic issues on certain topics according to the journal editorial policy. Authors featured in the journal represent renowned scientific laboratories and institutes from different countries, including large international collaborations. There are globally recognized researchers among the authors: Nobel laureates and recipients of other awards, and members of national academies of sciences and international scientific societies.
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