Hall–Petch Relationship in Aluminum and Aluminum Alloys

Encyclopedia of Aluminum and Its Alloys Pub Date : 2018-11-16 DOI:10.1201/9781351045636-140000234

R. Armstrong

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引用次数: 4

Abstract

The mechanical properties of aluminum are shown to be of special importance beginning from the early 20th-century production of the material in single crystal and polycrystalline form. Experimental and theoretical researches of the time were concerned with particular influence of polycrystalline microstructure and the presence of crystal (grain) boundaries on both the material strength properties and on relation of those same properties to those for the full range of metal and alloy structures. Now it is well established that a relatively low value of the microstructural stress intensity, kε, is obtained for aluminum in the generalized Hall–Petch relation for its stress–strain, σε − ε, behavior depending on the average grain diameter, l, with intercept (friction) stress, σ0ε, which relation is given as: id="unequ63_1">σε=σ0ε+kεl−1/2With hindsight, taking σε = σ0ε provided the first connection between single crystal and polycrystalline strength measurements in the pioneering Taylor theory of plasticity proposed for aluminum and other face-centered cubic metals. Later, conventional and ultrafine grain size measurements are shown to verify the fuller H–P dependence. The present account builds onto the early history. A description is given for temperature, strain rate, and alloy-dependent mechanical property measurements. An understanding of the total measurements is described in terms of a dislocation pile-up model description for the relation. Emphasis is given to kε for pure aluminum and related metals being determined by cross-slip forced at grain boundaries. Particular attention is given to two characteristics of the metal mechanical behavior: (1) very high rate loading deformations leading to shock and shock-less isentropic compression experiments and (2) important grain size influences on nanopolycrystalline material behaviors. Additional results are presented on H–P aspects of the material strain ageing, shear banding, ductile fracturing, and fatigue behaviors.

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铝和铝合金中的Hall-Petch关系

从20世纪早期生产单晶和多晶材料开始，铝的机械性能就被证明是特别重要的。当时的实验和理论研究关注的是多晶微观结构和晶体(晶粒)边界的存在对材料强度性能的特殊影响，以及这些性能与各种金属和合金组织的强度性能之间的关系。在广义Hall-Petch关系中，铝的应力-应变σε−ε随平均晶粒直径的变化规律与截距(摩擦)应力σ0ε的关系较低，关系式为:id="unequ63_1">σε=σ0ε+kε 1 - 1/2事后看来，采用σε=σ0ε为铝和其他面心立方金属塑性理论的先驱Taylor理论提供了单晶和多晶强度测量之间的第一个联系。随后，常规和超细晶粒尺寸测量证明了更充分的hp依赖性。现在的叙述建立在早期历史的基础上。给出了温度、应变率和合金相关力学性能测量的描述。根据位错堆积模型描述了对总测量值的理解。重点讨论了纯铝及相关金属的kε是由晶界处的交叉滑移所决定的。特别关注金属力学行为的两个特征:(1)非常高的加载变形导致冲击和无冲击等熵压缩实验;(2)晶粒尺寸对纳米多晶材料行为的重要影响。在材料应变老化、剪切带化、韧性断裂和疲劳行为的hp方面提出了额外的结果。

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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Encyclopedia of Aluminum and Its Alloys

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