Viscosity of Metallic Glass-Forming Liquids Based on Zr by Fast-Scanning Calorimetry

Computational Materials Science eJournal Pub Date : 2021-10-01 DOI:10.2139/ssrn.3848997

R. Al-Mukadam, I. K. Goetz, M. Stolpe, J. Deubener

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引用次数: 13

Abstract

Fast-scanning calorimetry was applied to retrieve the viscosity of supercooled liquids of the Zr-based bulk metallic glasses (BMGs) Vitreloy 105 and AMZ4 for temperatures from standard glass transition down to ~0.78T_g/T. Characteristic temperatures of the glass transition were translated into viscosity values by means of composition-independent shift factors based on the equivalency between structural relaxation and viscous flow. The extended MYEGA model with a fragile term dominant at high-temperatures and a strong term dominant at low-temperatures describes the entire viscous range. The analysis revealed that Vitreloy 105 and AMZ4 are strong liquids for log₁₀η ≥ 4.9–5.5. In turn, the fragile-to-strong crossover is centred on 0.69T_g/T for Vitreloy 105 and on 0.66T_g/T for AMZ4. The extent of the fragile-to-strong transition was found to be larger for Vitreloy 105 than for AMZ4, while their values agreed well with the inverse relation between transition factor and kinetic fragility of the strong regime established for BMG-forming liquids.

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基于Zr的快速扫描量热法测定金属玻璃成型液的粘度

采用快速扫描量热法测定了zr基大块金属玻璃(bmg) Vitreloy 105和AMZ4在标准玻璃转变至~0.78Tg/T时的过冷液体粘度。基于结构弛豫和粘性流动的等效性，通过与组分无关的位移因子将玻璃化转变的特征温度转化为粘度值。扩展的MYEGA模型在高温下以脆弱项为主，在低温下以强项为主，描述了整个粘性范围。分析表明，在log10η≥4.9 ~ 5.5范围内，Vitreloy 105和AMZ4为强液体。反过来，脆弱-强交叉集中在0.69Tg/T的Vitreloy 105和0.66Tg/T的AMZ4。与AMZ4相比，Vitreloy 105的脆性向强转变的程度更大，而它们的值与为bmg形成液体建立的强体系的转变因子与动力学脆性之间的反比关系吻合得很好。

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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Computational Materials Science eJournal

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