TY - JOUR
T1 - Mechanically active materials in three-dimensional mesostructures
AU - Ning, Xin
AU - Yu, Xinge
AU - Wang, Heling
AU - Sun, Rujie
AU - Corman, R. E.
AU - Li, Haibo
AU - Lee, Chan Mi
AU - Xue, Yeguang
AU - Chempakasseril, Aditya
AU - Yao, Yao
AU - Zhang, Ziqi
AU - Luan, Haiwen
AU - Wang, Zizheng
AU - Xia, Wei
AU - Feng, Xue
AU - Ewoldt, Randy H.
AU - Huang, Yonggang
AU - Zhang, Yihui
AU - Rogers, John A.
N1 - Publisher Copyright:
© 2018 The Authors, some rights reserved.
PY - 2018/9/14
Y1 - 2018/9/14
N2 - Complex, three-dimensional (3D) mesostructures that incorporate advanced, mechanically active materials are of broad, growing interest for their potential use in many emerging systems. The technology implications range from precision-sensing microelectromechanical systems, to tissue scaffolds that exploit the principles of mechanobiology, to mechanical energy harvesters that support broad bandwidth operation. The work presented here introduces strategies in guided assembly and heterogeneous materials integration as routes to complex, 3D microscale mechanical frameworks that incorporatemultiple, independently addressable piezoelectric thin-film actuators for vibratory excitation and precise control. The approach combines transfer printing as a scheme formaterials integrationwith structural buckling as ameans for 2D-to-3D geometric transformation, for designs that range from simple, symmetric layouts to complex, hierarchical configurations, on planar or curvilinear surfaces. Systematic experimental and computational studies reveal the underlying characteristics and capabilities, including selective excitation of targeted vibrational modes for simultaneous measurements of viscosity and density of surrounding fluids. The results serve as the foundations for unusual classes of mechanically active 3D mesostructures with unique functions relevant to biosensing, mechanobiology, energy harvesting, and others.
AB - Complex, three-dimensional (3D) mesostructures that incorporate advanced, mechanically active materials are of broad, growing interest for their potential use in many emerging systems. The technology implications range from precision-sensing microelectromechanical systems, to tissue scaffolds that exploit the principles of mechanobiology, to mechanical energy harvesters that support broad bandwidth operation. The work presented here introduces strategies in guided assembly and heterogeneous materials integration as routes to complex, 3D microscale mechanical frameworks that incorporatemultiple, independently addressable piezoelectric thin-film actuators for vibratory excitation and precise control. The approach combines transfer printing as a scheme formaterials integrationwith structural buckling as ameans for 2D-to-3D geometric transformation, for designs that range from simple, symmetric layouts to complex, hierarchical configurations, on planar or curvilinear surfaces. Systematic experimental and computational studies reveal the underlying characteristics and capabilities, including selective excitation of targeted vibrational modes for simultaneous measurements of viscosity and density of surrounding fluids. The results serve as the foundations for unusual classes of mechanically active 3D mesostructures with unique functions relevant to biosensing, mechanobiology, energy harvesting, and others.
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U2 - 10.1126/sciadv.aat8313
DO - 10.1126/sciadv.aat8313
M3 - Article
C2 - 30225368
AN - SCOPUS:85053468183
SN - 2375-2548
VL - 4
JO - Science Advances
JF - Science Advances
IS - 9
M1 - eaat8313
ER -