超弹性纳米晶镍钛合金中与晶粒尺寸相关的电阻率-应变响应的相场研究

Yongji Li, Jianping Lin, Zhihao Zhao
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引用次数: 0

摘要

超弹性镍钛合金的电阻率随形变而发生显著变化,使其成为一种极具吸引力的传感应用材料。然而,人们对晶粒尺寸(GS)对镍钛合金电性能的影响缺乏全面的了解。为了弥补这一不足,我们开发了一种新型电子机械耦合相场模拟模型,并通过实验研究确定了关键参数。结果表明,电阻率与应变之间的关系发生了显著变化,随着 GS 的增加,从准线性模式过渡到片状非线性模式。观察到的变化主要受马氏体转变的影响,其特点是从均匀模式过渡到局部模式。随着 GS 的增加,电阻率在峰值应变时的总变化最初会下降,随后趋于稳定。这是因为 GS 通过应力和相变程度对电阻率的变化产生了两种相反的影响。此外,滞后和马氏体部分滞后的共同影响导致电阻率滞后随着 GS 的减小而持续减小。这项研究加深了人们对 GS 如何影响镍钛合金电阻率-应变响应的理解,并为未来的传感性能调节奠定了基础,拓展了其作为智能材料的多功能性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Phase field study on the grain size dependent electrical resistivity-strain response in superelastic nanocrystalline NiTi alloys
The superelastic NiTi alloy's electrical resistivity exhibits significant variations in response to deformation, making it a highly attractive material for sensing applications. However, there exists a lack of comprehensive knowledge of the effects of grain size (GS) on the electrical properties of NiTi alloy. To address this gap, a novel electro-mechanical coupled phase field simulation model is developed, with crucial parameters determined through experimental investigations. The results demonstrate a notable change in the relationship between electrical resistivity and strain, transitioning from a quasi-linear pattern to a piecewise nonlinear one as the GS increases. The observed modification is found to be primarily influenced by the martensitic transformation, characterized by a transition from a uniform mode to a localized mode. As the GS increases, there is an initial drop in the total change of electrical resistivity at peak strain, followed by a subsequent stabilization. This is because the GS, through the stress and the degree of phase transformation, exerts two opposing effects on the variation of electrical resistivity. Furthermore, the combined influence of hysteresis and hysteresis in the martensite fraction contributes to a consistent decrease in resistivity hysteresis as the GS diminishes. This study improves the understanding of how GS affects NiTi alloy's electrical resistivity-strain response and lays the foundation for future sensing performance regulation, expanding its multi-functionality as an intelligent material.
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