Optimization of In Situ Formation of a Titanium Carbide Nanohybrid via Mechanical Alloying Using Stearic Acid and Carbon Nanotubes as Carbon Sources

IF 3 Q2 MATERIALS SCIENCE, COMPOSITES Journal of Composites Science Pub Date : 2023-12-02 DOI:10.3390/jcs7120502

M. L. Camacho-Rios, G. Herrera-Pérez, Marco Antonio Ruiz Esparza-Rodríguez, Raúl Pérez-Bustamante, John Edison García-Herrera, J. Betancourt-Cantera, D. Lardizábal‐Gutiérrez

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Abstract

The current work shows the optimization of the preparation of nanosized titanium carbide in situ through mechanical alloying. Metallic titanium powders, along with two carbon sources, carbon nanotubes, and stearic acid, were used to reduce the particle size (around 11 nm) using an SPEX 800 high-energy mill. The combined use of 2 wt % of these carbon sources and n-heptane as a liquid process control agent proved crucial in generating nanoscale powder composites through a simple and scalable synthesis process within a 4 h timeframe. The uses of 20 wt % of both carbon sources were compared to determine the ability of carbon nanotubes to form carbides and the decomposition of process control agent during mechanical milling. The structure of the composites and starting materials were evaluated through X-ray diffraction and Raman spectroscopy, while the morphology features (average particle size and shape) were monitored via scanning electron microscopy and transmission electron microscopy.

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利用硬脂酸和碳纳米管作为碳源，通过机械合金优化碳化钛纳米杂化的原位形成

本研究通过机械合金化的方法，对原位制备纳米碳化钛进行了优化。金属钛粉，以及两种碳源，碳纳米管和硬脂酸，使用SPEX 800高能磨机减小颗粒尺寸(约11纳米)。事实证明，在4小时内通过简单且可扩展的合成工艺生成纳米级粉末复合材料，将2%的碳源和正庚烷作为液体过程控制剂的组合使用至关重要。在机械铣削过程中，比较了两种碳源的20%的使用情况，以确定碳纳米管形成碳化物的能力和过程控制剂的分解。通过x射线衍射和拉曼光谱对复合材料和起始材料的结构进行了评价，并通过扫描电镜和透射电镜对其形貌特征(平均粒径和形状)进行了监测。

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