Achieving symmetric snap-through buckling via designed magnetic actuation

IF 11.7 1区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Science Advances Pub Date : 2025-05-14 DOI:10.1126/sciadv.adw1259

Yingchao Zhang, Weicheng Huang, Mingchao Liu, Jing Yu, Huajian Gao

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引用次数: 0

Abstract

Symmetric snap-through buckling, although both theoretically achievable and practically advantageous, has remained rare in bistable systems, with most studies favoring asymmetric snapping due to its lower energy barrier. Previous observations of symmetric snapping have been limited to high loading rates. In this work, we present a universal strategy to achieve symmetric snapping under quasi-static conditions by designing magnetization (M)–interface patterns that effectively suppress asymmetric modes. A simplified theoretical model demonstrates that this behavior results from the interplay between pitchfork and saddle-node bifurcations, with predictions validated through simulations and experiments using hard magnetic elastomers. Resisting forces generated by multiple M-interfaces counteract asymmetric snapping, enabling distinct symmetric configurations. Extending this approach to higher-order symmetric snapping, we uncover a quasi-linear scaling law between critical fields and snapping order. These findings establish a robust framework for designing snapping systems with enhanced control and predictability, as demonstrated by a mechanical-magnetic snapping switch, paving the way for advanced applications in precision engineering and magnetic-mechanical actuation.

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通过设计磁致动实现对称卡扣

对称屈曲虽然在理论上可以实现，在实践中也很有利，但在双稳态系统中仍然很少见，大多数研究都倾向于非对称屈曲，因为它的能量势垒较低。以前对对称断裂的观察仅限于高加载速率。在这项工作中，我们提出了一种在准静态条件下通过设计有效抑制不对称模式的磁化(M)界面模式来实现对称剪切的通用策略。一个简化的理论模型表明，这种行为是干草叉和鞍节点分叉之间相互作用的结果，并通过硬磁弹性体的模拟和实验验证了预测。由多个m -接口产生的阻力抵消了不对称的折断，使不同的对称配置成为可能。将此方法推广到高阶对称吸波，揭示了临界场与吸波阶之间的拟线性标度规律。这些发现为设计具有增强控制和可预测性的断裂系统建立了一个强大的框架，正如机械磁断裂开关所证明的那样，为精密工程和磁机械驱动的先进应用铺平了道路。

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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来源期刊

Science Advances 综合性期刊-综合性期刊

CiteScore

21.40

自引率

1.50%

发文量

1937

审稿时长

29 weeks

期刊介绍： Science Advances, an open-access journal by AAAS, publishes impactful research in diverse scientific areas. It aims for fair, fast, and expert peer review, providing freely accessible research to readers. Led by distinguished scientists, the journal supports AAAS's mission by extending Science magazine's capacity to identify and promote significant advances. Evolving digital publishing technologies play a crucial role in advancing AAAS's global mission for science communication and benefitting humankind.