Litcius/Paper detail

Sunlight-powered self-excited oscillators for sustainable autonomous soft robotics

Yusen Zhao, Qiaofeng Li, Zixiao Liu, Yousif Alsaid, Pengju Shi, Mohammad Khalid Jawed, Ximin He

2023Science Robotics149 citationsDOI

Abstract

As the field of soft robotics advances, full autonomy becomes highly sought after, especially if robot motion can be powered by environmental energy. This would present a self-sustained approach in terms of both energy supply and motion control. Now, autonomous movement can be realized by leveraging out-of-equilibrium oscillatory motion of stimuli-responsive polymers under a constant light source. It would be more advantageous if environmental energy could be scavenged to power robots. However, generating oscillation becomes challenging under the limited power density of available environmental energy sources. Here, we developed fully autonomous soft robots with self-sustainability based on self-excited oscillation. Aided by modeling, we have successfully reduced the required input power density to around one-Sun level through a liquid crystal elastomer (LCE)-based bilayer structure. The autonomous motion of the low-intensity LCE/elastomer bilayer oscillator "LiLBot" under low energy supply was achieved by high photothermal conversion, low modulus, and high material responsiveness simultaneously. The LiLBot features tunable peak-to-peak amplitudes from 4 to 72 degrees and frequencies from 0.3 to 11 hertz. The oscillation approach offers a strategy for designing autonomous, untethered, and sustainable small-scale soft robots, such as a sailboat, walker, roller, and synchronized flapping wings.

Topics & Concepts

Soft roboticsRobotOscillation (cell signaling)RoboticsMechanical energyComputer scienceEnergy harvestingPower (physics)Artificial intelligenceMaterials scienceMechanical engineeringControl theory (sociology)NanotechnologyPhysicsEngineeringChemistryBiochemistryQuantum mechanicsControl (management)Advanced Materials and MechanicsAdvanced Sensor and Energy Harvesting MaterialsMicro and Nano Robotics