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Main Author: Su, Xiaoyu
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2410.12200
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author Su, Xiaoyu
author_facet Su, Xiaoyu
contents Shape transformation is crucial for the survival, adaptation, predation, defense, and reproduction of organisms in complex environments. It also serves as a key mechanism for the development of various applications, including soft robotics, biomedical systems, and flexible electronic devices. However, among the various deformation actuation modes, the design of deformable structures, the material response characteristics, and the miniaturization of devices remain challenges. As materials and structures are scaled down to the microscale, their performance becomes strongly correlated with size, leading to significant changes in, or even the failure of, many physical mechanisms that are effective at the macroscale. Additionally, electrostatic forces, surface tension, and viscous forces dominate at the microscale, making it difficult for structures to deform or causing them to fracture easily during deformation. Moreover, despite the prominence of acoustic actuation among various deformation drive modes, it has received limited attention. Here, we introduce an acoustical shape-morphing micromachine (ASM) that provides shape variability through a pair of microbubbles and the micro-hinges connecting them. When excited by external acoustic field, interaction forces are generated between these microbubbles, providing the necessary force and torque for the deformation of the entire micromachine within milliseconds. We established programmable design principles for ASM, enabling the forward and inverse design of acoustic deformation, precise programming, and information storage. Furthermore, we adjusted the amplitude of acoustic excitation to demonstrate the controllable switching of the micromachine among various modes. By showcasing the micro bird, we illustrated the editing of multiple modes, achieving a high degree of controllability, stability, and multifunctionality.
format Preprint
id arxiv_https___arxiv_org_abs_2410_12200
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Acoustic shape-morphing micromachines
Su, Xiaoyu
Applied Physics
Shape transformation is crucial for the survival, adaptation, predation, defense, and reproduction of organisms in complex environments. It also serves as a key mechanism for the development of various applications, including soft robotics, biomedical systems, and flexible electronic devices. However, among the various deformation actuation modes, the design of deformable structures, the material response characteristics, and the miniaturization of devices remain challenges. As materials and structures are scaled down to the microscale, their performance becomes strongly correlated with size, leading to significant changes in, or even the failure of, many physical mechanisms that are effective at the macroscale. Additionally, electrostatic forces, surface tension, and viscous forces dominate at the microscale, making it difficult for structures to deform or causing them to fracture easily during deformation. Moreover, despite the prominence of acoustic actuation among various deformation drive modes, it has received limited attention. Here, we introduce an acoustical shape-morphing micromachine (ASM) that provides shape variability through a pair of microbubbles and the micro-hinges connecting them. When excited by external acoustic field, interaction forces are generated between these microbubbles, providing the necessary force and torque for the deformation of the entire micromachine within milliseconds. We established programmable design principles for ASM, enabling the forward and inverse design of acoustic deformation, precise programming, and information storage. Furthermore, we adjusted the amplitude of acoustic excitation to demonstrate the controllable switching of the micromachine among various modes. By showcasing the micro bird, we illustrated the editing of multiple modes, achieving a high degree of controllability, stability, and multifunctionality.
title Acoustic shape-morphing micromachines
topic Applied Physics
url https://arxiv.org/abs/2410.12200