Remote actuation based on magnetically responsive pillar arrays

Smart actuators, integrated with high aspect-ratio structures and stimuli-responsive materials, can take more diverse tasks skillfully. Although great advances have been achieved over the past few years, it is still difficult in manipulating the small objects such as the transporting and grasping them under the remote untethered condition. Inspired by the ciliary structures on biological organs, a magnetically responsive actuator with hierarchical pillars on the surface of the film is designed and proposed, which allows active, fast, and dynamic manipulation over the force and speed of a small object by taking an external magnetic field. Magnetic pillars of different morphologies were fabricated by a modified soft lithographic method involving inking and imprinting processes. The magnetic-force conversion unit was constructed by magnetically responsive pillar arrays. Upon applying an external magnetic field, these pillars can rhythmically bend and recover in a controlled manner, and the generated force can be used to drive the small object to move or capture the small object. All these was further addressed from experimental and theoretical perspectives. This magnetically responsive actuator demonstrates reliable actuating performance with instant field responses. No complex mechanical and electrical control systems are required. Thus, the combined use of high aspect-ratio structures and stimuli-responsive materials will facilitate many other applications such as surface engineering, soft actuators and robotics in the future.

Automated summary

This study proposes a smart actuator with magnetically responsive pillars on the surface, which allows for active and dynamic manipulation of small objects through an external magnetic field. The actuator demonstrates reliable performance and instant field responses without complex control systems.