直径-长度比对金纳米线机械疲劳和循环行为的影响：分子动力学研究

IF 1.6 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

The European Physical Journal B Pub Date : 2025-04-21 DOI:10.1140/epjb/s10051-025-00924-3

Muhammad Salsabil Nur Gunawan, Adam Fajri Asyidik, Tabina Putri Pintoro, Iwan Halim Sahputra

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引用次数: 0

摘要

金纳米线（AuNWs）表现出优异的机械性能，使其在纳米级电子学中具有前景。然而，它们在循环载荷下的机械可靠性，特别是径长比和拉拔速率的影响，仍然没有得到充分的了解。本研究通过分子动力学模拟研究这些因素对aunw机械疲劳行为的影响，解决了这一知识差距。采用应力应变分析和共邻分析（CNA）对循环变形过程中的力学响应和结构演化进行了评价。研究结果表明，较小的aunw（如直径为1 nm）由于位错形核有限而发生快速应变硬化，导致高应力能力但脆性破坏。相比之下，更大的aunw （3-9 nm直径）表现出更大的塑性调节和局部变形，延缓了破坏并提高了机械稳定性。拉拔速率进一步调节了这些行为，较高的拉拔速率增加峰值应力，较低的拉拔速率促进塑性松弛。通过阐明直径、载荷条件和疲劳行为之间的相互作用，本研究为纳米材料的结构可靠性提供了新的见解，为其在先进纳米级应用中的优化设计提供了基础。图形抽象

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Impact of diameter-to-length ratio on mechanical fatigue and cyclic behavior of gold nanowires: a molecular dynamics study

Gold nanowires (AuNWs) exhibit exceptional mechanical properties, making them promising for nanoscale electronics. However, their mechanical reliability under cyclic loading, particularly the effects of diameter-to-length ratio and pulling rate, remains insufficiently understood. This study addresses this knowledge gap by investigating the impact of these factors on the mechanical fatigue behavior of AuNWs using molecular dynamics simulations. Stress–strain analyses and common neighbor analysis (CNA) were employed to assess mechanical responses and structural evolution during cyclic deformation. The findings reveal that smaller AuNWs (e.g., 1 nm diameter) undergo rapid strain hardening due to limited dislocation nucleation, resulting in high stress capacity but brittle failure. In contrast, larger AuNWs (3–9 nm diameters) exhibit greater plastic accommodation and localized deformation, delaying failure and enhancing mechanical stability. The pulling rate further modulates these behaviors, with higher rates increasing peak stresses and lower rates promoting plastic relaxation. By elucidating the interplay between diameter, loading conditions, and fatigue behavior, this study provides novel insights into the structural reliability of AuNWs, offering a foundation for their optimized design in advanced nanoscale applications.