Structural mechanism of reverse alpha -> gamma transformation and strengthening of Fe-Ni alloys

Sagaradze V. V.; Kataeva N. V.; Kabanova I. G.; Zavalishin V. A.; Valiullin A. I.; Klyukina M. F.

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Structural mechanism of reverse alpha -> gamma transformation and strengthening of Fe-Ni alloys

机译：铁镍合金反向α→γ相变和强化的结构机理

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Fe-32% Ni alloy subjected to slow heating to a temperature below A (s) at a rate of 0.01 K/min demonstrates the untwinning and appearance of an intermediate E > phase with an hcp lattice and lattice parameters a = 2.535, c = 4.132 , and c/a = 1.63. Slow heating to 430-490A degrees C leads to the formation of nanocrystalline austenite enriched in nickel, which substantially increases the hardness of martensite. The formation of austenite in the Fe-32% Ni alloy, which is a mixture of martensite with 20-30% nanocrystalline austenite, during its rapid heating to 600A degrees C occurs via the bulk mechanism with short-range atomic diffusion. In this case, the diffusion does not eliminate the concentration micro-inhomogeneity of the alloy in nickel but leads to the reorientation of gamma-phase nanocrystals, almost eliminates the dislocation structure, and removes the strengthening by phase hardening.

机译：Fe-32％Ni合金以0.01 K / min的速度缓慢加热到低于A（s）的温度，表明具有hcp晶格和晶格参数a = 2.535，c = 4.132和c / a = 1.63。缓慢加热至430-490A摄氏度会导致形成富含镍的纳米晶奥氏体，从而大大提高了马氏体的硬度。 Fe-32％Ni合金中的奥氏体形成是马氏体与20-30％纳米晶奥氏体的混合物，在其快速加热至600A的过程中，是通过具有短程原子扩散的本体机制而发生的。在这种情况下，扩散不会消除镍中合金的浓度微观不均匀性，而是会导致γ相纳米晶体重新取向，几乎消除位错结构，并消除通过相硬化而产生的强化。

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《The Physics of Metals and Metallography》 |2014年第7期|共11页
作者
Sagaradze V. V.; Kataeva N. V.; Kabanova I. G.; Zavalishin V. A.; Valiullin A. I.; Klyukina M. F.;
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正文语种 eng
中图分类金属学与热处理;
关键词
Fe-Ni austenitic alloys; martensitic alpha -gt; gamma transformation; nanocrystalline gamma phase; intermediate epsilon phase; structural mechanism; phase hardening; strengthening; L1(0) ordering;

机译：Fe-Ni奥氏体合金;马氏体α→γ相变;纳米晶γ相;中间ε相;结构机理;相硬化;强化;L1（0）有序;

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1. Structural mechanism of reverse alpha -> gamma transformation and strengthening of Fe-Ni alloys [J] . Sagaradze V. V., Kataeva N. V., Kabanova I. G., The Physics of Metals and Metallography . 2014,第7期

机译：铁镍合金反向α→γ相变和强化的结构机理
2. Structural mechanism of reverse α→γ transformation and new functional properties of Fe-Ni austenitic alloys [J] . V.V. Sagaradze, I.G. Kabanova, N.V. Kataeva, Materials science forum . 2013,第期

机译：Fe-Ni奥氏体合金的反向→α→γ相变的结构机理和新的功能性能
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4. Structural mechanism of reverse α→ γ transformation and new functional properties of Fe-Ni austenitic alloys [C] . V.V. Sagaradze, I.G. Kabanova, N.V. Kataeva, European symposium on martensitic transformations . 2013

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Structural mechanism of reverse alpha -> gamma transformation and strengthening of Fe-Ni alloys

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