High strength Ni matrix TiO2 composites by supercritical CO2 assisted Co-electrodeposition with different sizes of TiO2 particle

IF 2.8 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC Micro and Nano Engineering Pub Date : 2023-09-01 DOI:10.1016/j.mne.2023.100219
Yu-An Chien, Chun-Yi Chen, Tomoyuki Kurioka, Masato Sone, Tso-Fu Mark Chang
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Abstract

High strength Ni matrix TiO2 composites are prepared by co-electrodeposition with an electrolyte composed of Ni Watts bath, surfactants, CO2 in the supercritical fluid state and various sizes of TiO2 particles. The surfactants and supercritical CO2 (SC-CO2) are used to emulsify the aqueous Ni Watts bath to promote the incorporation of TiO2 particles into the Ni matrix. TiO2 particles with three different average sizes are used in the co-electrodeposition to evaluate the effect on properties of the Ni-TiO2 composites. The grain sizes of the Ni matrix in the composites are compared from the X-ray diffraction results and the Scherrer eq. A refined average grain size in the Ni matrix is observed when using TiO2 particles with a larger size. The TiO2 is evaluated by energy-dispersive X-ray spectroscopy (EDX), and the TiO2 distribution is quantified by the coefficient of variation (cov) of the local density of Ti from the EDX result. The TiO2 content attained 4.5 wt% with the lowest cov value (which suggests the most uniform distribution) in the composite when the smallest (21 nm) TiO2 particles are used. The TiO2 content achieves 22.3 wt% with the highest cov value (which suggests the least uniform distribution) when the largest (5 μm) TiO2 particles are used. Microhardness of the Ni-TiO2 composites is found to be highly depended on the cov value. Hence, the Ni-TiO2 composite prepared with the smallest TiO2 particles shows the highest microhardness at 1274 HV.

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超临界CO2辅助不同粒径TiO2电沉积高强度Ni基TiO2复合材料
通过与由Ni Watts浴、表面活性剂、超临界流体状态下的CO2和各种尺寸的TiO2颗粒组成的电解质共同电沉积制备了高强度Ni基TiO2复合材料。表面活性剂和超临界CO2(SC-CO2)用于乳化含水Ni Watts浴,以促进TiO2颗粒结合到Ni基体中。在共电沉积中使用了三种不同平均尺寸的TiO2颗粒来评估对Ni-TiO2复合材料性能的影响。根据X射线衍射结果和Scherrer方程比较了复合材料中Ni基体的晶粒尺寸。当使用具有较大尺寸的TiO2颗粒时,观察到Ni基体中的精细平均晶粒尺寸。通过能量色散X射线光谱(EDX)评估TiO2,并通过来自EDX结果的Ti局部密度的变异系数(cov)量化TiO2分布。当使用最小(21nm)的TiO2颗粒时,TiO2含量达到4.5wt%,在复合物中具有最低的cov值(这表明分布最均匀)。当使用最大(5μm)的TiO2颗粒时,TiO2含量达到22.3wt%,具有最高的cov值(这表明分布最不均匀)。研究发现,Ni-TiO2复合材料的显微硬度高度依赖于cov值。因此,用最小的TiO2颗粒制备的Ni-TiO2复合材料在1274HV下显示出最高的显微硬度。
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来源期刊
Micro and Nano Engineering
Micro and Nano Engineering Engineering-Electrical and Electronic Engineering
CiteScore
3.30
自引率
0.00%
发文量
67
审稿时长
80 days
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