Shear Viscosity of Liquid metals and alloys: Experiments and Atomic Characterization.

液态金属和合金的剪切粘度：实验和原子表征。

• 批准号: RGPIN-2014-06226
• 负责人: Shankar, Sumanth
• 金额: $ 2.11万
• 依托单位: McMaster University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2014
• 资助国家: 加拿大
• 起止时间: 2014-01-01 至 2015-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=567671
• 关键词: Shear; Viscosity; Liquid; metals; alloys

The main objective of this study is to evaluate, characterize and quantify the flow behavior (shear stress as a function of shear rate) and shear viscosity of liquid metals and alloys that hold both academic and commercial significance. The research involves three interacting themes carried out in tandem: rheological experiments, atomic structure characterization through diffraction experiments and modeling through molecular dynamics and first principle formulations. The successful completion of this initiative and characterization of the flow behavior of liquid metals and alloys will have significant and far reaching impact in several areas of fundamental and applied materials science: casting (direct chill, continuous and near net shaped), joining (welding, soldering and brazing), single crystal growth, zone-refining and metal matrix composite processing to name a few. The design of many advanced manufacturing processes involving liquid metals and alloys requires a comprehensive understanding of transport properties in the liquid phases (such as the shear viscosity and associated relaxation time). These transport properties depend intimately on the microscopic structure and atomic composition of these liquids and our knowledge of this correlation is quite limited at present. While phenomenological models, either entirely empirical, or based on certain approximations of the microscopic processes involved in liquid transport have been used to predict transport phenomena in liquids, the gap between experiments and these models remains quite large. Our recent exploratory experiments and publications demonstrate that contrary to conventional wisdom, a wide variety of liquid metals and alloys exhibit non-Newtonian behavior, which are more pronounced at low shear rate regimes; this behavior is attributed to a transition in the governing mechanism from the resistance of the metallic bonding to shear, to momentum transfer between atom layers with increasing strain rate. At low shear rates the resistance offered to the flow of these liquids from the strong atomic bonds existing in the short range atomic order of the liquid structure dominates while at higher shear rates, the momentum transfer between atomic layers dominates the flow mechanism. This work motivates us to examine the fundamental mechanisms governing flow behavior in liquid metals and alloys through rigorous experiments, and atomistic structure evaluation and simulations, with a view to correlate and quantify the shear viscosity and the impact of liquid atomic structure on the same. Currently, our research group has the only high temperature rheometer in the North America, capable of evaluating rheological properties of liquids with a maximum temperature of about 1873 K in an environment chamber; acquired through our recent partnership with the Switzerland rheology equipment manufacturer, Anton Paar. Pure liquid metals and alloys of commercial interests such as Fe, steel, Si, Al alloys, Mg alloys, Cu alloy and Pb free solder alloys would be used as materials for rheological characterization (shear stress as a function of shear rate) with the high temperature rheometer. Diffraction experiments with both the Neutron and Synchrotron beam sources will evaluate structure information of liquid metals under controlled applied shear. Non-equilibrium molecular dynamics simulations using the popular molecular dynamics software packages, including VASP and LAMMPS will be formulated; attention will be restricted to determining and validating shear viscosity in pure liquid metals and simple binary alloys, and interatomic potentials appropriate for a study of shear viscosity will be employed. Through this study, we will gain useful insights into the physics governing this behavior.

这项研究的主要目的是评估、表征和量化具有学术和商业意义的液态金属和合金的流动行为(剪切应力作为剪切速率的函数)和剪切粘度。这项研究涉及三个相互作用的主题：流变性实验、通过衍射实验表征原子结构以及通过分子动力学和第一性原理公式进行建模。这一倡议的成功完成和液态金属及合金流动行为的表征将对基础材料科学和应用材料科学的几个领域产生重大而深远的影响：铸造(直接激冷、连续和近净成形)、连接(焊接、焊接和铜焊)、单晶生长、区域精炼和金属基复合材料加工。许多涉及液态金属和合金的先进制造工艺的设计需要全面了解液态中的传输特性(如剪切粘度和相关的松弛时间)。这些输运性质密切依赖于这些液体的微观结构和原子组成，目前我们对这种相关性的了解相当有限。虽然唯象模型已经被用来预测液体中的传输现象，无论是完全经验的，还是基于液体传输所涉及的微观过程的某些近似，但这些模型与实验之间的差距仍然很大。我们最近的探索性实验和出版物表明，与传统观点相反，许多液态金属和合金表现出非牛顿行为，这种行为在低剪切速率下更加明显；这种行为归因于支配机制的转变，从金属键合到剪切的阻力，到原子层之间随着应变率的增加而产生的动量转移。在低剪切速率下，液体结构中存在的强原子键对流体流动的阻力占主导地位，而在较高剪切速率下，原子层之间的动量传递主导流动机制。这项工作促使我们通过严格的实验、原子结构评估和模拟来研究控制液态金属和合金流动行为的基本机制，以期关联和量化剪切粘度以及液态原子结构对其的影响。目前，我们的研究小组拥有北美唯一的高温流变仪，能够在环境舱中评估最高温度约为1873K的液体的流变性；这是我们最近与瑞士流变学设备制造商Anton Paar合作获得的。在高温流变仪上，纯液态金属及其合金，如铁、钢、硅、铝合金、镁合金、铜合金和无铅焊料合金将被用作流变特性(剪切应力与剪切速率的函数)的材料。用中子源和同步束源进行的衍射实验将评估受控外加剪切下液态金属的结构信息。将使用流行的分子动力学软件包(包括VASP和LAMMPS)进行非平衡分子动力学模拟；注意力将仅限于确定和验证纯液态金属和简单二元合金的剪切粘度，并将采用适合于研究剪切粘度的原子间势。通过这项研究，我们将对支配这一行为的物理机制获得有用的见解。