Three-dimensional mesostructures as high-temperature growth templates, electronic cellular scaffolds, and self-propelled microrobots

Recent work demonstrates that processes of stress release in prestrained elastomeric substrates can guide the assembly of sophisticated 3D micro/nanostructures in advanced materials. Reported application examples include soft electronic components, tunable electromagnetic and optical devices, vibrat...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2017-10, Vol.114 (45)
Main Authors: Yan, Zheng, Han, Mengdi, Shi, Yan, Badea, Adina, Yang, Yiyuan, Kulkarni, Ashish, Hanson, Erik, Kandel, Mikhail E., Wen, Xiewen, Zhang, Fan, Luo, Yiyue, Lin, Qing, Zhang, Hang, Guo, Xiaogang, Huang, Yuming, Nan, Kewang, Jia, Shuai, Oraham, Aaron W., Mevis, Molly B., Lim, Jaeman, Guo, Xuelin, Gao, Mingye, Ryu, Woomi, Yu, Ki Jun, Nicolau, Bruno G., Petronico, Aaron, Rubakhin, Stanislav S., Lou, Jun, Ajayan, Pulickel M., Thornton, Katsuyo, Popescu, Gabriel, Fang, Daining, Sweedler, Jonathan V., Braun, Paul V., Zhang, Haixia, Nuzzo, Ralph G., Huang, Yonggang, Zhang, Yihui, Rogers, John A.
Format: Article
Language:English
Subjects:
electronic cellular scaffolds
eutectics
MATERIALS SCIENCE
three-dimensional microstructures
three-dimensional printing
two-dimensional materials
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Summary:Recent work demonstrates that processes of stress release in prestrained elastomeric substrates can guide the assembly of sophisticated 3D micro/nanostructures in advanced materials. Reported application examples include soft electronic components, tunable electromagnetic and optical devices, vibrational metrology platforms, and other unusual technologies, each enabled by uniquely engineered 3D architectures. A vast disadvantage of these systems is that the elastomeric substrates, while essential to the assembly process, can impose significant engineering constraints in terms of operating temperatures and levels of dimensional stability; they also prevent the realization of 3D structures in freestanding forms. In this work, we introduce concepts in interfacial photopolymerization, nonlinear mechanics, and physical transfer that bypass these limitations. The results enable 3D mesostructures in fully or partially freestanding forms, with additional capabilities in integration onto nearly any class of substrate, from planar, hard inorganic materials to textured, soft biological tissues, all via mechanisms quantitatively described by theoretical modeling. Illustrations of these ideas include their use in 3D structures as frameworks for templated growth of organized lamellae from AgCl–KCl eutectics and of atomic layers of WSe2from vapor-phase precursors, as open-architecture electronic scaffolds for formation of dorsal root ganglion (DRG) neural networks, and as catalyst supports for propulsive systems in 3D microswimmers with geometrically controlled dynamics. Taken together, these methodologies establish a set of enabling options in 3D micro/nanomanufacturing that lie outside of the scope of existing alternatives.
ISSN:0027-8424
1091-6490