浓度梯度驱动的各向异性旋多分解动力学:金属合金的氮化

IF 1.2 4区 材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
K. Sasidhar, M. Gururajan, S. Meka
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引用次数: 0

摘要

摘要讨论了在具有弹性和界面能各向异性的立方晶体中,晶体取向的单向浓度梯度对旋节分解的影响。相场模拟表明,在这样的系统中发生的旋节分解的动力学取决于组成梯度的方向和旋节波动生长的优选结晶取向之间的取向差的程度;取向差越大,动力学越慢。这一现象已被用来解释在金属合金氮化过程中观察到的众所周知的晶粒取向相关的氮吸收动力学。文献中提出了氮化过程中晶粒取向相关的氮吸收动力学的几个可能原因。然而,这项研究表明,这种现象在具有旋节不稳定性的合金系统中无一例外地被观察到。已知这种系统中的N吸收动力学取决于旋节分解的动力学。因此,由于在多晶金属中存在表面定向的N组成梯度而发生的各向异性旋节分解动力学已被证明是该现象的更根本原因。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Concentration-gradient-driven anisotropic spinodal decomposition kinetics: nitriding of metallic alloys
ABSTRACT The effect of crystallographically oriented, unidirectional concentration gradients on spinodal decomposition in cubic crystalline solids with elastic and interfacial energy anisotropy is discussed. Phase-field simulations reveal that the kinetics of spinodal decomposition occurring in such systems is dependent on the degree of misorientation between the direction of composition gradient and the preferred crystallographic orientation for growth of spinodal fluctuations; the larger is the misorientation, the slower the kinetics. This phenomenon has been used to explain the well-known grain-orientation-dependent N-uptake kinetics observed during nitriding of metallic alloys. Several plausible causes have been proposed in the literature for the grain-orientation-dependent N-uptake kinetics during nitriding. However, this study reveals that this phenomenon is observed exclusively and without exception in alloy systems having a spinodal instability. The N-uptake kinetics in such systems is known to be dependent on the kinetics of spinodal decomposition. Consequently, anisotropic spinodal decomposition kinetics occurring owing to the presence of a surface-directed N-composition gradient in poly-crystalline metals has been shown to be a more fundamental cause for the phenomenon.
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来源期刊
Philosophical Magazine Letters
Philosophical Magazine Letters 物理-物理:凝聚态物理
CiteScore
2.60
自引率
0.00%
发文量
25
审稿时长
2.7 months
期刊介绍: Philosophical Magazine Letters is the rapid communications part of the highly respected Philosophical Magazine, which was first published in 1798. Its Editors consider for publication short and timely contributions in the field of condensed matter describing original results, theories and concepts relating to the structure and properties of crystalline materials, ceramics, polymers, glasses, amorphous films, composites and soft matter. Articles emphasizing experimental, theoretical and modelling studies on solids, especially those that interpret behaviour on a microscopic, atomic or electronic scale, are particularly appropriate. Manuscripts are considered on the strict condition that they have been submitted only to Philosophical Magazine Letters , that they have not been published already, and that they are not under consideration for publication elsewhere.
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