Exploiting Liquid Surface Tension in Microrobotics

Barbot, Antoine; Ortiz, Francisco; Bolopion, Aude; Gauthier, Michaël; Lambert, Pierre

doi:10.1146/annurev-control-062422-102559

Cited by 6 publications

(1 citation statement)

References 88 publications

(131 reference statements)

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“…There are many limitations, such as reduced efficiency, domination of surface effects at the microscale, and manufacturability for scaling down conventional actuation concepts from macro to microdomain. [17][18][19] Therefore, dedicated actuation mechanisms, novel materials, and advanced fabrication techniques are under development to address these issues. [20][21][22][23][24][25][26][27] For example, it is impossible to apply conventional electromagnetic motor-based actuation for microrobots used for targeted drug therapy for minimally invasive medicine because of the limited miniaturisation capability of the electromagnetic motors.…”

Section: Samith Hettiarachchimentioning

confidence: 99%

Actuation for flexible and stretchable microdevices

Roshan,

Mudugamuwa,

Cha

et al. 2024

Lab Chip

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Section: Samith Hettiarachchimentioning

confidence: 99%

Actuation for flexible and stretchable microdevices

Roshan,

Mudugamuwa,

Cha

et al. 2024

Lab Chip

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Self‐Propelled Morphing Matter for Small‐Scale Swimming Soft Robots

Huang,

Pinchin,

Lin

et al. 2024

Adv Funct Materials

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Aquatic insects have developed versatile locomotion mechanisms that have served as a source of inspiration for decades in the development of small‐scale swimming robots. However, despite recent advances in the field, efficient, untethered, and integrated powering, actuation, and control of small‐scale robots remains a challenge due to the out‐of‐equilibrium and dissipative nature of the driving physical and chemical phenomena. Here, we have designed small‐scale, bioinspired aquatic locomotors with programmable deterministic trajectories that integrate self‐propelled chemical motors and photoresponsive shape‐morphing structures. A Marangoni motor system is developed integrating structural protein networks that self‐regulate the release of chemical fuel with photochemical liquid crystal network (LCN) actuators that change their shape and deform in and out of the surface of water. While the diffusion of fuel from the motor system regulates the propulsion, the dissipative photochemical deformation of LCNs provides locomotors with control over the directionality of motion at the air‐water interface. This approach gives access to five different but interchangeable modes of locomotion within a single swimming robot via morphing of the soft structure. The proposed design, which mimics the mechanisms of surface gliding and posture change of semiaquatic insects such as water treaders, offers solutions for autonomous swimming soft robots via untethered and orthogonal power and control.

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Electricity‐Driven Strategies for Bioinspired Multifunctional Swimming Marangoni Robots Based on Super‐Aligned Carbon Nanotube Composites

Lin,

Qian,

Zhou

et al. 2024

Small

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Marangoni actuators that are propelled by surface tension gradients hold significant potential in small‐scale swimming robots. Nevertheless, the release of “fuel” for conventional chemical Marangoni actuators is not easily controllable, and the single swimming function also limits application areas. Constructing controllable Marangoni robots with multifunctions is still a huge challenge. Herein, inspired by water striders, electricity‐driven strategies are proposed for a multifunctional swimming Marangoni robot (MSMR), which is fabricated by super‐aligned carbon nanotube (SACNT) and polyimide (PI) composite. The MSMR consists of a Marangoni actuator and air‐ambient actuators. Owing to the temperature gradient generated by the electrical stimulation on the water surface, the Marangoni actuators can swim controllably with linear, turning, and rotary motions, mimicking the walking motion of water striders. In addition, the Marangoni actuators can also be driven by light. Importantly, the air‐ambient actuators fabricated by SACNT/PI bilayer structures demonstrate the function of grasping objects on the water surface when electrically Joule‐heated, mimicking the predation behavior of water striders. With the synergistic effect of the Marangoni actuator and air‐ambient actuators, the MSMR can navigate mazes with tunnels and grasp objects. This research will provide a new inspiration for smart actuators and swimming robots.

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Exploiting Liquid Surface Tension in Microrobotics

Cited by 6 publications

References 88 publications

Actuation for flexible and stretchable microdevices

Actuation for flexible and stretchable microdevices

Self‐Propelled Morphing Matter for Small‐Scale Swimming Soft Robots

Electricity‐Driven Strategies for Bioinspired Multifunctional Swimming Marangoni Robots Based on Super‐Aligned Carbon Nanotube Composites

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