Litcius/Paper detail

Bio-inspired and programmable Marangoni motor for highly maneuverable and adaptable S-aquabots

Yexi Zhou, Xiao Guan, Dazhe Zhao, Kai‐Jun Zhang, YongAn Huang, Junwen Zhong

2024eScience12 citationsDOIOpen Access PDF

Abstract

Mobility, environmental adaptability, and functionality are essential attributes of robots, but these become challenging for small-scale on-water robots, also referred to as S-aquabots. Herein, we propose a programmable Marangoni motor (PM-motor) to propel centimeter-scale S-aquabots with high maneuverability and adaptability. Lightweight, compact, flexible hybrid electronics are used to precisely release ethanol to achieve controllable propulsion, smart sensing, and wireless communication functions. The PM-motor utilizes the surface tension gradient generated by the ethanol, which is released from leaf-inspired veins and improves fuel efficiency by 3.5 times when compared with traditional Marangoni effect-propelled robots. As a result, the device’s endurance is up to ∼226 ​s for a navigation distance of ∼5 ​m with just 1.2 ​mL ethanol. Benefiting from the leaf-like shape and negligible noise production, the S-aquabots can also blend well with their surroundings. Autonomous response capability is demonstrated by guiding an S-aquabot with laser spots to complete a butterfly-shaped trajectory. Equipped with a mini-camera or digital sensors, untethered S-aquabots deployed on an outdoor pool can capture real-time videos or monitor long-term environmental conditions. This work is beneficial for inspiring insightful design strategies to develop S-aquabots with high practical potential. • S-aquabots with bio-inspired designs result in 3.5-fold better fuel utilization efficiency, can blend well with surroundings. • The trajectory of a moving S-aquabot can be precisely controlled using lightweight, compact, flexible hybrid electronics. • Untethered S-aquabots can transmit real-time video or detect long-term information about the surrounding environment.

Topics & Concepts

Marangoni effectComputer sciencePhysicsMechanicsConvectionMicro and Nano RoboticsUnderwater Vehicles and Communication SystemsModular Robots and Swarm Intelligence