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3D morphable systems via deterministic microfolding for vibrational sensing, robotic implants, and reconfigurable telecommunication

Lin Zhang, Zongwen Zhang, Hannah Weisbecker, Haifeng Yin, Yihan Liu, Tianhong Han, Ziheng Guo, Matt Berry, Binbin Yang, Xu Guo, Jacob J. Adams, Zhaoqian Xie, Wubin Bai

2022Science Advances10 citationsDOIOpen Access PDF

Abstract

DNA and proteins fold in three dimensions (3D) to enable functions that sustain life. Emulation of such folding schemes for functional materials can unleash enormous potential in advancing a wide range of technologies, especially in robotics, medicine, and telecommunication. Here, we report a microfolding strategy that enables formation of 3D morphable microelectronic systems integrated with various functional materials, including monocrystalline silicon, metallic nanomembranes, and polymers. By predesigning folding hosts and configuring folding pathways, 3D microelectronic systems in freestanding forms can transform across various complex configurations with modulated functionalities. Nearly all transitional states of 3D microelectronic systems achieved via the microfolding assembly can be easily accessed and modulated in situ, offering functional versatility and adaptability. Advanced morphable microelectronic systems including a reconfigurable microantenna for customizable telecommunication, a 3D vibration sensor for hand-tremor monitoring, and a bloomable robot for cardiac mapping demonstrate broad utility of these assembly schemes to realize advanced functionalities.

Topics & Concepts

MicroelectronicsEmulationComputer scienceRoboticsFolding (DSP implementation)EvolvabilityReconfigurabilityNeuromorphic engineeringRobotNanotechnologyComputer architectureMaterials scienceArtificial intelligenceTelecommunicationsEngineeringElectrical engineeringArtificial neural networkEconomic growthEconomicsBiologyEvolutionary biologyAdvanced Materials and MechanicsModular Robots and Swarm IntelligenceAdvanced Sensor and Energy Harvesting Materials
3D morphable systems via deterministic microfolding for vibrational sensing, robotic implants, and reconfigurable telecommunication | Litcius