基于二硫化钼的纳米涂层在微米级和纳米级的弹性和摩擦特性

IF 0.5 4区 工程技术 Q4 ENGINEERING, MECHANICAL
Mohammad Farooq Wani, F. I. Stepanov, E. V. Torskaya, I. V. Shkalei
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引用次数: 0

摘要

摘要-在 23 和 150°C 温度下使用纳米压痕法研究掺银和氟化钙的二硫化钼涂层。实验使用了 Nanoscan-4D 扫描纳米硬度计。考虑到压头的实际形状(通过光学轮廓仪确定),介绍了一种通过弹性压痕曲线确定涂层弹性特性的方法。涂层的弹性模量是根据两层弹性地基接触问题的精确解法确定的,同时考虑到测量系统的计算顺应性。牛顿法用于逆问题求解。问题的输入参数除了压头的几何形状和载荷外,还有压头和基体材料的弹性特性。在两种温度下,弹性压痕的最大载荷均为 10 mN。室温和 150°C 时的加载-卸载曲线非常接近(在实验误差范围内),这证明了弹性特性在所考虑的温度范围内的稳定性。计算得出的涂层弹性模量为 326 GPa。使用配备横向力传感器的同一装置,测定了涂层在不同负载(5、10 和 20 mN)下的滑动摩擦系数。这项研究可视为涂层与单个表面接触的物理模型。实验在 1 毫米长的直轨道上以 11 微米/秒的速度进行。实验表明,涂层具有抗摩擦性(摩擦系数在 0.033-0.078 之间)。摩擦系数随着载荷的增加而增大,这可能是由于涂层材料在相对较高的载荷下发生塑性变形而耗散了能量。关于存在塑性变形的结论是基于光学轮廓测量的结果,该结果显示在相对较高的载荷下,摩擦轨迹边缘的材料会发生塑性变形并被推挤。而在低负荷时,则观察不到这种现象。这种涂层可用于需要一到两次低摩擦系数应用的滑动摩擦装置。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The Elastic and Frictional Properties of Nanoscale Coatings Based on Molybdenum Disulfide at Micro and Nano Levels

The Elastic and Frictional Properties of Nanoscale Coatings Based on Molybdenum Disulfide at Micro and Nano Levels

The Elastic and Frictional Properties of Nanoscale Coatings Based on Molybdenum Disulfide at Micro and Nano Levels

Nanoindentation at temperatures of 23 and 150°C is used to study the coating of molybdenum disulfide doped with silver and calcium fluoride. The Nanoscan-4D scanning nanohardness tester was used for the experiments. A method is presented for determining the elastic properties of a coating from elastic indentation curves, taking into account the real shape of the indenter head, which is determined by optical profilometry. The elasticity modulus of the coating is determined based on the exact solution of the contact problem for a two-layered elastic foundation, taking into account the calculated compliance of the measurement system. Newton’s method is used for the inverse problem solution. The input parameters of the problem, in addition to the geometry of the indenter head and the load, are the elastic properties of the head and substrate materials. The elastic type of indentation was provided at maximal load of 10 mN for both temperatures. The loading–unloading curves at room temperature and at 150°C turned out to be close (within the experimental error), which proves the stability of the elastic properties in the considered temperature range. The calculated elastic modulus of the coating was 326 GPa. Using the same device, equipped with a lateral force sensor, the sliding friction coefficient of the coating was determined under different loads (5, 10, and 20 mN). Such a study can be considered as a physical model of the contact of the coating with a single asperity. The experiments were carried out on straight tracks 1 mm long at a speed of 11 µm/s. It is shown that the coatings are antifrictional (with friction coefficients in the range 0.033—0.078). The coefficient of friction increases with increasing load, which may be due to the dissipation of energy for plastic deformation of the coating material at relatively high loads. The conclusion about the presence of plastic deformation is based on the results of optical profilometry, which showed plastically deformed and pushed material along the edges of the friction track under relatively high loads. At low loads, this phenomenon is not observed. This coating can be used in sliding friction units that require one or two applications with a low friction coefficient.

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来源期刊
Journal of Friction and Wear
Journal of Friction and Wear ENGINEERING, MECHANICAL-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
1.50
自引率
28.60%
发文量
21
审稿时长
6-12 weeks
期刊介绍: Journal of Friction and Wear is intended to bring together researchers and practitioners working in tribology. It provides novel information on science, practice, and technology of lubrication, wear prevention, and friction control. Papers cover tribological problems of physics, chemistry, materials science, and mechanical engineering, discussing issues from a fundamental or technological point of view.
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