期刊
SCIENCE ROBOTICS
卷 7, 期 63, 页码 -出版社
AMER ASSOC ADVANCEMENT SCIENCE
DOI: 10.1126/scirobotics.abg2171
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资金
- Defense Advanced Research Projects Agency Young Faculty Award (DARPA YFA) [D18AP00041]
This multifunctional shape-morphing material combines elastomeric kirigami with an unconventional reversible plasticity mechanism in metal alloys to rapidly morph flat sheets into complex, load-bearing shapes, with reversibility and self-healing through phase change. It overcomes trade-offs in deformability and load-bearing capacity, and eliminates power requirements to sustain reconfigured shapes.
Biological organisms such as the octopus can reconfigure their shape and properties to perform diverse tasks. However, soft machines struggle to achieve complex configurations, morph into shape to support loads, and go between multiple states reversibly. Here, we introduce a multifunctional shape-morphing material with reversible and rapid polymorphic reconfigurability. We couple elastomeric kirigami with an unconventional reversible plasticity mechanism in metal alloys to rapidly (<0.1 seconds) morph flat sheets into complex, load-bearing shapes, with reversibility and self-healing through phase change. This kirigami composite overcomes trade-offs in deformability and load-bearing capacity and eliminates power requirements to sustain reconfigured shapes. We demonstrate this material through integration with onboard control, motors, and power to create a soft robotic morphing drone, which autonomously transforms from a ground to air vehicle and an underwater morphing machine, which can be reversibly deployed to collect cargo.
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