Crystallization, mechanical and electrochemical behavior of Al-Ce-TM (TM = Fe, Co, Ni and Cu) amorphous alloys

International journal of nanotechnology and nanomedicine Pub Date : 2019-11-15 DOI:10.33140/ijnn.04.02.06

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Abstract

Al86Ce10TM4 amorphous alloys (TM=Fe, Co, Ni and Cu) were fabricated using melt-spin fast-quenching method. The crystallization, mechanical and electrochemical behavior of the as-spun and the post-annealed alloys were investigated by X-ray diffraction (XRD), differential scanning calorimetry (DSC), micro-indentation and electrochemical techniques. It was found the completely amorphous Al86Ce10TM4 alloys (TM=Fe, Co, Ni and Cu) go through two crystallization processes, where the first exothermal peak represents nucleation of nano-crystalline particles and the second exothermal peak signifies growth of the nano-crystalline precipitates. Both the nucleation and growth processes rely on diffusion-controlled mechanism. The first onset crystallization temperature Tx1 associated with activation energy E1 and frequency factor Ko1 can be used to evaluate the thermal stability of the amorphous alloys while the second onset crystallization temperature Tx2 associated with activation energy E2 and frequency factor Ko2 can be taken to judge the thermal stability of ideal amorphous-nanocrystalline mixed structure in sustaining optimized mechanical and electrochemical properties. The as-spun and post-annealed alloys exhibit higher mechanical hardness (860~1180 MPa), corrosion resistance (10-8A/cm2 ) and high temperature endurance (284, 300 and 420°C for Al86Ce10Co4 , Al86Ce10Ni4 andAl86Ce10Fe4 , respectively) compared to hardness 500~600 MPa, corrosion resistance 10-7A/cm2 and high temperature durability 200°C of traditional Al crystalline alloys, manifesting the value on scientific studies and engineering applications of the Al86Ce10TM4 amorphous alloys.

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Al-Ce-TM (TM = Fe,Co, Ni和Cu)非晶合金的结晶、力学和电化学行为

采用熔体自旋快速淬火法制备了Al86Ce10TM4非晶合金(TM=Fe, Co, Ni和Cu)。采用x射线衍射(XRD)、差示扫描量热法(DSC)、微压痕和电化学技术研究了烧结前后合金的结晶、力学和电化学行为。结果表明，完全非晶Al86Ce10TM4合金(TM=Fe, Co, Ni和Cu)经历了两个结晶过程，其中第一个放热峰代表纳米晶颗粒的成核，第二个放热峰代表纳米晶析出相的生长。成核和生长过程都依赖于扩散控制机制。与活化能ye1和频率因子Ko1相关的第一次结晶温度Tx1可用于评价非晶合金的热稳定性，而与活化能E2和频率因子Ko2相关的第二次结晶温度Tx2可用于评价理想的非晶-纳米晶混合结构在保持最佳力学和电化学性能方面的热稳定性。与传统Al晶合金的硬度500~600 MPa、耐蚀性10 ~ 7a /cm2和耐高温性200℃相比，经纺丝和退火后的合金具有更高的机械硬度(860~1180MPa)、耐蚀性(10 ~ 8a /cm2)和耐高温性(Al86Ce10Co4、Al86Ce10Ni4和al86ce10fe4分别为284、300和420℃)，体现了Al86Ce10TM4非晶合金的科学研究和工程应用价值。

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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International journal of nanotechnology and nanomedicine

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