纯钛粗晶和细晶低温等离子体渗氮各向异性相变机理研究

IF 1.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Uspekhi Fiziki Metallov-Progress in Physics of Metals Pub Date : 2022-03-01 DOI:10.15407/ufm.23.01.090

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引用次数: 1

摘要

在623、673和723 K温度下，研究了多向锻造粗晶和细晶纯钛的渗氮过程。该过程采用高密度射频直流等离子体结合矩形空心阴极装置进行。结果表明，随着保温温度的升高，表面硬度显著提高。x射线衍射结果显示，由于形成了由δ-Ti2N、ε-Ti2N和TixNx组成的表面层，使得表面硬度增加。本文阐述了表面层形成的机理。我们还通过x射线衍射峰的右移观察到了氮化钛的各向异性相变。氮化过程中扩散的氮原子通过亚稳的δ-Ti2N向稳定的ε-Ti2N的结构转变引起晶体取向的变化。结构重建将继续形成TixNx以达到化学计量平衡。随着渗氮温度的升高，合金的表面组织更加致密。

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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Anisotropic Phase Transformation Mechanism on Coarse-Grained and Fine-Grained Pure Titanium at Low-Temperature Plasma Nitriding

The nitriding process of the coarse-grained and fine-grained pure titanium proceeded by multidirectional forging technique has been investigated at temperatures of 623, 673, and 723 K. The process was carried out by high-density radiofrequency-direct current plasma combined with a rectangular hollow cathode device. The result obtained is a significant increase in surface hardness with increasing holding temperature. The surface hardness increases due to forming a surface layer composed of δ-Ti2N, ε-Ti2N and TixNx observed from x-ray diffraction results. This paper explains the mechanism of surface layer formation. We also observed anisotropic phase transformation of titanium nitride through the right shift of the x-ray diffraction peaks. Diffused nitrogen atoms during the nitriding process cause a change in crystal orientation through structural transformation of the metastable δ-Ti2N to the stable ε-Ti2N. The structural reconstruction will continue by forming TixNx to achieve stoichiometric equilibrium. More compacting of the surface microstructure is also obtained by increasing nitriding temperature.

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来源期刊

Uspekhi Fiziki Metallov-Progress in Physics of Metals Multiple-

CiteScore

3.10

自引率

18.80%

发文量

审稿时长

13 weeks

期刊介绍： The review journal Uspehi Fiziki Metallov (abbreviated key-title: Usp. Fiz. Met.) was founded in 2000. In 2018, the journal officially obtained parallel title Progress in Physics of Metals (abbreviated title — Prog. Phys. Met.). The journal publishes articles (that has not been published nowhere earlier and are not being considered for publication elsewhere) comprising reviews of experimental and theoretical results in physics and technology of metals, alloys, compounds, and materials that possess metallic properties; reviews on monographs, information about conferences, seminars; data on the history of metal physics; advertising of new technologies, materials and devices. Scope of the Journal: Electronic Structure, Electrical, Magnetic and Optical Properties; Interactions of Radiation and Particles with Solids and Liquids; Structure and Properties of Amorphous Solids and Liquids; Defects and Dynamics of Crystal Structure; Mechanical, Thermal and Kinetic Properties; Phase Equilibria and Transformations; Interphase Boundaries, Metal Surfaces and Films; Structure and Properties of Nanoscale and Mesoscopic Materials; Treatment of Metallic Materials and Its Effects on Microstructure and Properties.