Electric current-induced solid-state crack healing and life extension

IF 8.3 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Acta Materialia Pub Date : 2024-11-14 DOI:10.1016/j.actamat.2024.120573

Swanand Telpande , Chandan Kumar , Deepak Sharma , Praveen Kumar

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Abstract

This study demonstrates the complete closure of a crack and subsequent materials healing via a solid-state process upon application of high-density electric current pulses. This novel method leverages the simultaneous generation of a high-temperature field near the crack tip, a compressive stress zone induced by temperature gradients, and a significant electromagnetic force acting in Mode I, all arising from the flow of electric current around the crack. Finite element-based analysis is employed to optimize the process parameters, ensuring the dominance of the compressive stress field over the tensile electromagnetic force near the crack tip. Conjugate experiments demonstrate that fatigue-induced edge cracks in a metallic material (e.g., SS 316) can be fully healed by applying electric current pulses with extended pulse-width (e.g., 200 ms) and high densities (e.g., 10⁶⁻10⁸ A/m²). Detailed microstructural analysis of the healed region reveals micro-void-free complete bonding between the crack faces, characterized by a narrow strip (<100 μm width) featuring small, recrystallized grains. The observed boundary migration, entrapment of cavities inside grains, and partial alignment of dislocation substructures across the original crack confirm the solid-state diffusion bonding responsible for the materials healing. The yield strength, ductility and fatigue life of the “healed” material are commendable and can be significantly improved to mimic those of as-received material after solutionizing heat treatment. Overall, this study introduces a novel method for controlled crack closure and materials healing in in-service components, offering the potential to extend their operational life significantly.

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电流诱导的固态裂缝愈合和寿命延长

这项研究展示了在应用高密度电流脉冲时，通过固态过程实现裂纹的完全闭合和随后的材料愈合。这种新方法利用了在裂纹尖端附近同时产生的高温场、由温度梯度诱发的压缩应力区以及作用于模式 I 的显著电磁力，所有这些都是由裂纹周围的电流流产生的。我们采用基于有限元的分析方法来优化工艺参数，确保压应力场在裂纹尖端附近比拉伸电磁力占优势。共轭实验证明，在金属材料（如 SS 316）中施加长脉宽（如 200 毫秒）和高密度（如 106-108 A/m2 ）的电流脉冲，疲劳诱发的边缘裂纹可以完全愈合。对愈合区域进行的详细微观结构分析表明，裂纹面之间无微小空隙，完全粘合在一起，形成了一条窄带（宽度为 100 微米），其特点是晶粒细小、再结晶。观察到的边界迁移、晶粒内部的空穴夹持以及位错子结构在原始裂纹上的部分排列，证实了固态扩散结合是材料愈合的原因。愈合 "材料的屈服强度、延展性和疲劳寿命都值得称赞，而且在固溶热处理后，其屈服强度、延展性和疲劳寿命都能得到显著提高，与原接收材料的屈服强度、延展性和疲劳寿命相仿。总之，这项研究引入了一种新方法，用于控制在役部件的裂缝闭合和材料愈合，从而有可能大大延长其使用寿命。

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来源期刊

Acta Materialia 工程技术-材料科学：综合

CiteScore

16.10

自引率

8.50%

发文量

801

审稿时长

53 days

期刊介绍： Acta Materialia serves as a platform for publishing full-length, original papers and commissioned overviews that contribute to a profound understanding of the correlation between the processing, structure, and properties of inorganic materials. The journal seeks papers with high impact potential or those that significantly propel the field forward. The scope includes the atomic and molecular arrangements, chemical and electronic structures, and microstructure of materials, focusing on their mechanical or functional behavior across all length scales, including nanostructures.