3D Tunable, Multiscale, and Multistable Vibrational Micro-Platforms Assembled by Compressive Buckling

Xin Ning; Heling Wang; Xinge Yu; Julio A.N.T. Soares; Zheng Yan; Kewang Nan; Gabriel Velarde; Yeguang Xue; Rujie Sun; Qiyi Dong; Haiwen Luan; Chan Mi Lee; Aditya Chempakasseril; Mengdi Han; Yiqi Wang; Luming Li; Yonggang Huang; Yihui Zhang; John A. Rogers

doi:10.1002/adfm.201605914

3D Tunable, Multiscale, and Multistable Vibrational Micro-Platforms Assembled by Compressive Buckling

Xin Ning, Heling Wang, Xinge Yu, Julio A.N.T. Soares, Zheng Yan, Kewang Nan, Gabriel Velarde, Yeguang Xue, Rujie Sun, Qiyi Dong, Haiwen Luan, Chan Mi Lee, Aditya Chempakasseril, Mengdi Han, Yiqi Wang, Luming Li, Yonggang Huang, Yihui Zhang, John A. Rogers

Research output: Contribution to journal › Article › peer-review

Abstract

Microelectromechanical systems remain an area of significant interest in fundamental and applied research due to their wide ranging applications. Most device designs, however, are largely 2D and constrained to only a few simple geometries. Achieving tunable resonant frequencies or broad operational bandwidths requires complex components and/or fabrication processes. The work presented here reports unusual classes of 3D micromechanical systems in the form of vibratory platforms assembled by controlled compressive buckling. Such 3D structures can be fabricated across a broad range of length scales and from various materials, including soft polymers, monocrystalline silicon, and their composites, resulting in a wide scope of achievable resonant frequencies and mechanical behaviors. Platforms designed with multistable mechanical responses and vibrationally decoupled constituent elements offer improved bandwidth and frequency tunability. Furthermore, the resonant frequencies can be controlled through deformations of an underlying elastomeric substrate. Systematic experimental and computational studies include structures with diverse geometries, ranging from tables, cages, rings, ring-crosses, ring-disks, two-floor ribbons, flowers, umbrellas, triple-cantilever platforms, and asymmetric circular helices, to multilayer constructions. These ideas form the foundations for engineering designs that complement those supported by conventional, micro-electromechanical systems, with capabilities that could be useful in systems for biosensing, energy harvesting, and others.

Original language	English (US)
Article number	1605914
Journal	Advanced Functional Materials
Volume	27
Issue number	14
DOIs	https://doi.org/10.1002/adfm.201605914
State	Published - Apr 11 2017

Keywords

3D microstructures
compressive buckling
micro-electromechanical systems
vibrational modes

ASJC Scopus subject areas

General Chemistry
General Materials Science
Condensed Matter Physics

Online availability

10.1002/adfm.201605914

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Ning, X., Wang, H., Yu, X., Soares, J. A. N. T., Yan, Z., Nan, K., Velarde, G., Xue, Y., Sun, R., Dong, Q., Luan, H., Lee, C. M., Chempakasseril, A., Han, M., Wang, Y., Li, L., Huang, Y., Zhang, Y., & Rogers, J. A. (2017). 3D Tunable, Multiscale, and Multistable Vibrational Micro-Platforms Assembled by Compressive Buckling. Advanced Functional Materials, 27(14), Article 1605914. https://doi.org/10.1002/adfm.201605914

Ning, X, Wang, H, Yu, X, Soares, JANT, Yan, Z, Nan, K, Velarde, G, Xue, Y, Sun, R, Dong, Q, Luan, H, Lee, CM, Chempakasseril, A, Han, M, Wang, Y, Li, L, Huang, Y, Zhang, Y & Rogers, JA 2017, '3D Tunable, Multiscale, and Multistable Vibrational Micro-Platforms Assembled by Compressive Buckling', Advanced Functional Materials, vol. 27, no. 14, 1605914. https://doi.org/10.1002/adfm.201605914

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title = "3D Tunable, Multiscale, and Multistable Vibrational Micro-Platforms Assembled by Compressive Buckling",

abstract = "Microelectromechanical systems remain an area of significant interest in fundamental and applied research due to their wide ranging applications. Most device designs, however, are largely 2D and constrained to only a few simple geometries. Achieving tunable resonant frequencies or broad operational bandwidths requires complex components and/or fabrication processes. The work presented here reports unusual classes of 3D micromechanical systems in the form of vibratory platforms assembled by controlled compressive buckling. Such 3D structures can be fabricated across a broad range of length scales and from various materials, including soft polymers, monocrystalline silicon, and their composites, resulting in a wide scope of achievable resonant frequencies and mechanical behaviors. Platforms designed with multistable mechanical responses and vibrationally decoupled constituent elements offer improved bandwidth and frequency tunability. Furthermore, the resonant frequencies can be controlled through deformations of an underlying elastomeric substrate. Systematic experimental and computational studies include structures with diverse geometries, ranging from tables, cages, rings, ring-crosses, ring-disks, two-floor ribbons, flowers, umbrellas, triple-cantilever platforms, and asymmetric circular helices, to multilayer constructions. These ideas form the foundations for engineering designs that complement those supported by conventional, micro-electromechanical systems, with capabilities that could be useful in systems for biosensing, energy harvesting, and others.",

keywords = "3D microstructures, compressive buckling, micro-electromechanical systems, vibrational modes",

author = "Xin Ning and Heling Wang and Xinge Yu and Soares, {Julio A.N.T.} and Zheng Yan and Kewang Nan and Gabriel Velarde and Yeguang Xue and Rujie Sun and Qiyi Dong and Haiwen Luan and Lee, {Chan Mi} and Aditya Chempakasseril and Mengdi Han and Yiqi Wang and Luming Li and Yonggang Huang and Yihui Zhang and Rogers, {John A.}",

note = "Funding Information: X.N., H.W., and X.Y. contributed equally to this work. Y.X. acknowleges the support from the Ryan Fellowship and the Northwestern University International Institute for Nanotechnology. Y.H. acknowledges the support from the NSF (Grant Nos. DMR-1121262, CMMI-1300846, and 1534120). Y.H. and J.A.R. acknowledge the support from the NSF (Grant No. CMMI-1400169) and the NIH (Grant No. R01EB019337). Y.Z. acknowledges the support from the National Science Foundation of China (Grant No. 11672152). J.A.R. acknowledges the support from the U.S. Department of Energy, Office of Science, Basic Energy Sciences under Award No. DEFG02-07ER46471. Publisher Copyright: {\textcopyright} 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim",

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doi = "10.1002/adfm.201605914",

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T1 - 3D Tunable, Multiscale, and Multistable Vibrational Micro-Platforms Assembled by Compressive Buckling

AU - Ning, Xin

AU - Wang, Heling

AU - Yu, Xinge

AU - Soares, Julio A.N.T.

AU - Yan, Zheng

AU - Nan, Kewang

AU - Velarde, Gabriel

AU - Xue, Yeguang

AU - Sun, Rujie

AU - Dong, Qiyi

AU - Luan, Haiwen

AU - Lee, Chan Mi

AU - Chempakasseril, Aditya

AU - Han, Mengdi

AU - Wang, Yiqi

AU - Li, Luming

AU - Huang, Yonggang

AU - Zhang, Yihui

AU - Rogers, John A.

N1 - Funding Information: X.N., H.W., and X.Y. contributed equally to this work. Y.X. acknowleges the support from the Ryan Fellowship and the Northwestern University International Institute for Nanotechnology. Y.H. acknowledges the support from the NSF (Grant Nos. DMR-1121262, CMMI-1300846, and 1534120). Y.H. and J.A.R. acknowledge the support from the NSF (Grant No. CMMI-1400169) and the NIH (Grant No. R01EB019337). Y.Z. acknowledges the support from the National Science Foundation of China (Grant No. 11672152). J.A.R. acknowledges the support from the U.S. Department of Energy, Office of Science, Basic Energy Sciences under Award No. DEFG02-07ER46471. Publisher Copyright: © 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

PY - 2017/4/11

Y1 - 2017/4/11

N2 - Microelectromechanical systems remain an area of significant interest in fundamental and applied research due to their wide ranging applications. Most device designs, however, are largely 2D and constrained to only a few simple geometries. Achieving tunable resonant frequencies or broad operational bandwidths requires complex components and/or fabrication processes. The work presented here reports unusual classes of 3D micromechanical systems in the form of vibratory platforms assembled by controlled compressive buckling. Such 3D structures can be fabricated across a broad range of length scales and from various materials, including soft polymers, monocrystalline silicon, and their composites, resulting in a wide scope of achievable resonant frequencies and mechanical behaviors. Platforms designed with multistable mechanical responses and vibrationally decoupled constituent elements offer improved bandwidth and frequency tunability. Furthermore, the resonant frequencies can be controlled through deformations of an underlying elastomeric substrate. Systematic experimental and computational studies include structures with diverse geometries, ranging from tables, cages, rings, ring-crosses, ring-disks, two-floor ribbons, flowers, umbrellas, triple-cantilever platforms, and asymmetric circular helices, to multilayer constructions. These ideas form the foundations for engineering designs that complement those supported by conventional, micro-electromechanical systems, with capabilities that could be useful in systems for biosensing, energy harvesting, and others.

AB - Microelectromechanical systems remain an area of significant interest in fundamental and applied research due to their wide ranging applications. Most device designs, however, are largely 2D and constrained to only a few simple geometries. Achieving tunable resonant frequencies or broad operational bandwidths requires complex components and/or fabrication processes. The work presented here reports unusual classes of 3D micromechanical systems in the form of vibratory platforms assembled by controlled compressive buckling. Such 3D structures can be fabricated across a broad range of length scales and from various materials, including soft polymers, monocrystalline silicon, and their composites, resulting in a wide scope of achievable resonant frequencies and mechanical behaviors. Platforms designed with multistable mechanical responses and vibrationally decoupled constituent elements offer improved bandwidth and frequency tunability. Furthermore, the resonant frequencies can be controlled through deformations of an underlying elastomeric substrate. Systematic experimental and computational studies include structures with diverse geometries, ranging from tables, cages, rings, ring-crosses, ring-disks, two-floor ribbons, flowers, umbrellas, triple-cantilever platforms, and asymmetric circular helices, to multilayer constructions. These ideas form the foundations for engineering designs that complement those supported by conventional, micro-electromechanical systems, with capabilities that could be useful in systems for biosensing, energy harvesting, and others.

KW - 3D microstructures

KW - compressive buckling

KW - micro-electromechanical systems

KW - vibrational modes

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3D Tunable, Multiscale, and Multistable Vibrational Micro-Platforms Assembled by Compressive Buckling

Abstract

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