Collaborative Research: Tailoring Energy Landscapes to Harness the Multistability for Reconfigurable 3D Buckled Structures

合作研究：定制能源景观以利用可重构 3D 屈曲结构的多稳定性

• 批准号: 2020476
• 负责人: Teng Zhang
• 金额: $ 25.57万
• 依托单位: Syracuse University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2020
• 资助国家: 美国
• 起止时间: 2020-08-15 至 2024-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2020476&HistoricalAwards=false
• 关键词: Collaborative; Research; Tailoring; Energy; Landscapes

This grant will focus on fundamental studies on the multistability of three-dimensional (3D) structures for well-controlled, active architectural reconfigurability. Reconfigurable structures can actively change their geometries and thereby their functionalities upon external stimuli (like mechanical forces, magnetic fields, electric fields, hydration, temperature, and pressure). Such smart, stimuli-responsive structures have a diverse range of applications in deployable solar panels, electromagnetic metamaterials, photonics, biomedical devices, soft robotics, metasurfaces, and many others. Most existing reconfiguration mechanisms, however, require persistent external stimuli to maintain the deformed shape. Reconfigurability through harnessing structural instabilities has emerged as a popular and powerful means of designing various multifunctional reconfigurable devices that can maintain their deformed shape without the need for persistent external stimuli. Despite intensive studies, the difficulty in realizing well-controlled architectural reconfigurability has significantly hindered the rational design of reconfigurable structures, especially for those composed of thin films. This research project will focus on understanding the fundamental relationship between the geometry and mechanical properties of 3D thin-film structures and their multistability and identifying the energy-efficient reconfiguration path from one stable state to another. In addition to the research activities, the project will contribute to the education of students at the graduate, undergraduate, and K-12 levels by supporting interdisciplinary doctoral student training, undergraduate research opportunities, and outreach activities to grade 6-9 girls and K-5 students from underrepresented groups.The objective of this project is to unravel the fundamental mechanics that govern architectural reconfiguration among multistable, symmetric and asymmetric configurations of flexible, three-dimensional (3D) thin-film structures. To achieve this objective, the specific aims of this project include: (1) maximize the energy barrier and eliminate intermediate local minima between stable states of 3D thin-film structures through energy landscape biasing, and (2) minimize the energy cost for shape change from one local minimum state to another, and realize the reconfigurability of 3D thin-film structures through magnetic force control. The research outcomes of the work will significantly advance our knowledge in the mechanics of multistable structures by (i) establishing relations between geometries and material compositions of thin-film structures and the energy landscape of different stable states, and (ii) determining the active forces to efficiently maneuver the structure from one stable state to another following the minimum energy path. In addition, the project will ultimately facilitate the design of well-controlled, smart reconfigurable structures and generate broad impacts on other fields, including physics, materials science, and smart materials and structures.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

该补助金将集中在三维（3D）结构的多稳定性的基础研究，以实现良好的控制，积极的建筑可重构性。可重构结构可以在外部刺激（如机械力、磁场、电场、水合作用、温度和压力）下主动改变其几何形状，从而改变其功能。这种智能的刺激响应结构在可部署太阳能电池板、电磁超材料、光子学、生物医学设备、软机器人、超表面等许多领域都有广泛的应用。然而，大多数现有的重构机制需要持续的外部刺激来维持变形的形状。通过利用结构不稳定性的可重构性已经成为设计各种多功能可重构设备的流行和强大的手段，这些设备可以在不需要持续的外部刺激的情况下保持其变形的形状。尽管深入的研究，实现良好的控制架构的可重构性的困难，显着阻碍了可重构结构的合理设计，特别是对于那些由薄膜。该研究项目将侧重于了解3D薄膜结构的几何形状和机械特性与其多稳定性之间的基本关系，并确定从一个稳定状态到另一个稳定状态的节能重构路径。除了研究活动外，该项目还将通过支持跨学科博士生培训，本科生研究机会，和外联活动，以6-9年级的女孩和幼儿园，这个项目的目标是揭示在多稳态，柔性三维（3D）薄膜结构的对称和非对称配置。为了实现这一目标，本项目的具体目标包括：（1）通过能量横向偏置最大化能量势垒，消除3D薄膜结构稳定状态之间的中间局部极小值;（2）通过磁力控制，最小化从一个局部极小状态到另一个局部极小状态的形状变化的能量成本，并实现3D薄膜结构的可重构性。该工作的研究成果将通过（i）建立薄膜结构的几何形状和材料成分与不同稳定状态的能量景观之间的关系，以及（ii）确定有效地将结构从一个稳定状态操纵到另一个稳定状态的主动力，从而显着推进我们在多稳态结构力学方面的知识。此外，该项目最终将促进良好控制的智能可重构结构的设计，并对其他领域产生广泛的影响，包括物理学、材料科学和智能材料与结构。该奖项反映了NSF的法定使命，并通过使用基金会的智力价值和更广泛的影响评审标准进行评估，被认为值得支持。

项目成果

Autonomous self-burying seed carriers for aerial seeding

• DOI: 10.1038/s41586-022-05656-3
• 发表时间: 2023-02-16
• 期刊: NATURE
• 影响因子: 64.8
• 作者: Luo, Danli;Maheshwari, Aditi;Yao, Lining
• 通讯作者: Yao, Lining

Reconfiguration of multistable 3D ferromagnetic mesostructures guided by energy landscape surveys

• DOI: 10.1016/j.eml.2021.101428
• 发表时间: 2021-07-13
• 期刊: EXTREME MECHANICS LETTERS
• 影响因子: 4.7
• 作者: Li, Yi;Avis, Samuel J.;Wang, Xueju
• 通讯作者: Wang, Xueju