机械合金化的驱动机制:实验和分子动力学讨论

I.F Vasconcelos , R.S de Figueiredo
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引用次数: 8

摘要

Mössbauer光谱学、x射线衍射和差示扫描量热法对fcc fe45at进行了研究。机械合金化获得的% Cu纳米晶固溶体。这些结果得到了分子动力学模拟的支持,并用于讨论机械合金化中的一些模型。动能甚至是它的一个函数,似乎是驱动磨机内部反应的参数。撞击频率和粉末质量似乎只在时间尺度上起作用。毛细压力的存在有利于纳米晶粒的合金化。尽管如此,由冲击提供的额外能量被证明是启动这一过程所必需的。最终产品似乎是应变/应力场和材料响应的函数。
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Driving mechanisms on mechanical alloying: experimental and molecular dynamics discussions

Mössbauer spectroscopy, X-rays diffraction and differential scanning calorimetry are used to study a fcc Fe 45at.% Cu nanocrystalline solid solution obtained by mechanical alloying. These results supported by molecular dynamics simulations are used to discuss some models in mechanical alloying. The kinetic energy ou even a function of it appears to be the parameter driving the reactions inside the mill. Impact frequency and powder mass seem to contribute only on the time scale. A capilarity pressure is shown to exist in order to alloy the nanocrystalline grains. Despite this, an extra energy, provided by the shocks, is shown to be necessary to start up the process. Final product appears to be a function of strains/stress fields and material response.

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