Abstract
Collective control of mobile microrobotic swarms is indispensable for their potential high‐impact applications in targeted drug delivery, medical diagnostics, parallel micromanipulation, and environmental sensing and remediation. Without integrated electronics for sensing and actuation, current microrobotic systems should rely on physical interactions among individual microrobots for local communication and cooperation. Here, it is shown that mobile microrobotic swarms with well‐defined collective behavior can be designed by engineering magnetic interactions among individual units. Microrobots, dynamically self‐assembled from magnetic microparticles into linear chains, locomote on surfaces in response to a precessing magnetic field. Control over precessing magnetic field allows engineering attractive and repulsive interactions among microrobots and, thus, collective order with well‐defined spatial organization and stable parallel operation over macroscale distances (≈1 cm) and through confining obstacles. The design approach described here addresses programmable assembly, propulsion, and collective behavior of dense mobile microrobot swarms simultaneously by engineering magnetic interactions and dynamic actuation of microrobots. The presented approach will advance swarm microrobotics by enabling facile and rapid formation of self‐organized and reconfigurable microrobotic swarms with programmable collective order and stability.
Highlights
Collective control of mobile microrobotic swarms is indispensable for their micromanipulation, microsurgery, sensing, environmental remediation, and drug potential high-impact applications in targeted drug delivery, medical diagdelivery applications at the microscale nostics, parallel micromanipulation, and environmental sensing and remediation
Upon application of a global magnetic field (B), induced magnetic dipole moments of superparamagnetic microparticles align with the applied field and particles attract each other along their dipoles
When a magnetic field precessing about a precession axis w with a semicone angle (ψ = acos(B.w) = 70°) is applied at a small angular frequency (ω/2π = 1 Hz), particles assemble into chains (Figure S1, Supporting Information; Movies S1, and S2, Supporting Information)
Summary
Collective control of mobile microrobotic swarms is indispensable for their micromanipulation, microsurgery, sensing, environmental remediation, and drug potential high-impact applications in targeted drug delivery, medical diagdelivery applications at the microscale nostics, parallel micromanipulation, and environmental sensing and remediation. Without integrated electronics for sensing and actuation, current microrobotic systems should rely on physical interactions among individual microrobots for local communication and cooperation. It is shown (
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