Reconfigurable magnetic microrobot swarm: Multimode transformation, locomotion, and manipulation

Magnetic microrobot swarms collectively perform tasks in a confined environment through multimode transformation and locomotion. Swimming microrobots that are energized by external magnetic fields exhibit a variety of intriguing collective behaviors, ranging from dynamic self-organization to coherent motion; however, achieving multiple, desired collective modes within one colloidal system to emulate high environmental adaptability and enhanced tasking capabilities of natural swarms is challenging. Here, we present a strategy that uses alternating magnetic fields to program hematite colloidal particles into liquid, chain, vortex, and ribbon-like microrobotic swarms and enables fast and reversible transformations between them. The chain is characterized by passing through confined narrow channels, and the herring school–like ribbon procession is capable of large-area synchronized manipulation, whereas the colony-like vortex can aggregate at a high density toward coordinated handling of heavy loads. Using the developed discrete particle simulation methods, we investigated generation mechanisms of these four swarms, as well as the “tank-treading” motion of the chain and vortex merging. In addition, the swarms can be programmed to steer in any direction with excellent maneuverability, and the vortex’s chirality can be rapidly switched with high pattern stability. This reconfigurable microrobot swarm can provide versatile collective modes to address environmental variations or multitasking requirements; it has potential to investigate fundamentals in living systems and to serve as a functional bio-microrobot system for biomedicine.

[1]  E O Wilson,et al.  The Sociogenesis of Insect Colonies , 1985, Science.

[2]  D. Marr,et al.  Surface-enabled propulsion and control of colloidal microwheels , 2016, Nature Communications.

[3]  Tiantian Xu,et al.  On-Demand Disassembly of Paramagnetic Nanoparticle Chains for Microrobotic Cargo Delivery , 2017, IEEE Transactions on Robotics.

[4]  Lidong Yang,et al.  Pattern generation and motion control of a vortex-like paramagnetic nanoparticle swarm , 2018, Int. J. Robotics Res..

[5]  M Cristina Marchetti,et al.  Athermal phase separation of self-propelled particles with no alignment. , 2012, Physical review letters.

[6]  Fernando Peruani,et al.  Emergent vortices in populations of colloidal rollers , 2015, Nature Communications.

[7]  Mauro Birattari,et al.  Autonomous task sequencing in a robot swarm , 2018, Science Robotics.

[8]  Li Zhang,et al.  Dumbbell Fluidic Tweezers for Dynamical Trapping and Selective Transport of Microobjects , 2017 .

[9]  Ignacio Pagonabarraga,et al.  Emergent hydrodynamic bound states between magnetically powered micropropellers , 2017, Science Advances.

[10]  Alfons van Blaaderen,et al.  Directing Colloidal Self‐Assembly with Biaxial Electric Fields , 2009 .

[11]  Jean-Baptiste Caussin,et al.  Emergence of macroscopic directed motion in populations of motile colloids , 2013, Nature.

[12]  Sung Chul Bae,et al.  Colloidal Superstructures Programmed into Magnetic Janus Particles , 2015, Advanced materials.

[13]  Hugues Chaté,et al.  Collective motion of vibrated polar disks. , 2010, Physical review letters.

[14]  Erik Luijten,et al.  Linking synchronization to self-assembly using magnetic Janus colloids , 2012, Nature.

[15]  Markus Bär,et al.  Large-scale collective properties of self-propelled rods. , 2009, Physical review letters.

[16]  S. Granick,et al.  Rotating crystals of magnetic Janus colloids. , 2015, Soft matter.

[17]  Sijia Wang,et al.  Electric-field–induced assembly and propulsion of chiral colloidal clusters , 2015, Proceedings of the National Academy of Sciences.

[18]  S. Leibler,et al.  Self-organization of microtubules and motors , 1997, Nature.

[19]  Alexey Snezhko,et al.  Magnetic manipulation of self-assembled colloidal asters. , 2011, Nature materials.

[20]  Pietro Tierno,et al.  Reconfigurable swarms of nematic colloids controlled by photoactivated surface patterns. , 2014, Angewandte Chemie.

[21]  Andrea Prosperetti,et al.  Wall effects on a rotating sphere , 2010, Journal of Fluid Mechanics.

[22]  Jie Zhang,et al.  Reconfiguring active particles by electrostatic imbalance. , 2016, Nature materials.

[23]  Li Zhang,et al.  Selective trapping and manipulation of microscale objects using mobile microvortices. , 2012, Nano letters.

[24]  Aleksandar Donev,et al.  Unstable fronts and motile structures formed by microrollers , 2016, Nature Physics.

[25]  Thomas Speck,et al.  Dynamical clustering and phase separation in suspensions of self-propelled colloidal particles. , 2013, Physical review letters.

[26]  Hui Xie,et al.  Magnetically Actuated Peanut Colloid Motors for Cell Manipulation and Patterning. , 2018, ACS nano.

[27]  Alexey Snezhko,et al.  Manipulation of emergent vortices in swarms of magnetic rollers , 2018, Nature Communications.

[28]  Joseph Wang,et al.  Micro/nanorobots for biomedicine: Delivery, surgery, sensing, and detoxification , 2017, Science Robotics.

[29]  T. Mullin,et al.  The interaction between rotationally oscillating spheres and solid boundaries in a Stokes flow , 2018, Journal of Fluid Mechanics.

[30]  E. Purcell Life at Low Reynolds Number , 2008 .

[31]  Zhiguang Wu,et al.  Light-Activated Active Colloid Ribbons. , 2017, Angewandte Chemie.

[32]  Li Zhang,et al.  Ultra-extensible ribbon-like magnetic microswarm , 2018, Nature Communications.

[33]  C. Ybert,et al.  Dynamic clustering in active colloidal suspensions with chemical signaling. , 2012, Physical review letters.

[34]  Vicsek,et al.  Novel type of phase transition in a system of self-driven particles. , 1995, Physical review letters.

[35]  John R. Blake,et al.  Fundamental singularities of viscous flow , 1974 .

[36]  Pietro Tierno,et al.  Overdamped dynamics of paramagnetic ellipsoids in a precessing magnetic field. , 2009, Physical review. E, Statistical, nonlinear, and soft matter physics.

[37]  I. Pagonabarraga,et al.  Propulsion and hydrodynamic particle transport of magnetically twisted colloidal ribbons , 2017 .

[38]  H. Chaté,et al.  Onset of collective and cohesive motion. , 2004, Physical review letters.

[39]  Radhika Nagpal,et al.  Programmable self-assembly in a thousand-robot swarm , 2014, Science.

[40]  Andreas Kaiser,et al.  Flocking ferromagnetic colloids , 2017, Science Advances.

[41]  Li Zhang,et al.  Bio-inspired magnetic swimming microrobots for biomedical applications. , 2013, Nanoscale.

[42]  S. Melle,et al.  Microstructure evolution in magnetorheological suspensions governed by Mason number. , 2003, Physical review. E, Statistical, nonlinear, and soft matter physics.

[43]  R Di Leonardo,et al.  Effective interactions between colloidal particles suspended in a bath of swimming cells. , 2011, Physical review letters.

[44]  Ofer Feinerman,et al.  Ant groups optimally amplify the effect of transiently informed individuals , 2015, Nature Communications.

[45]  David J. Pine,et al.  Living Crystals of Light-Activated Colloidal Surfers , 2013, Science.

[46]  Hartmut Löwen,et al.  Fission and fusion scenarios for magnetic microswimmer clusters , 2016, Nature Communications.

[47]  Ignacio Pagonabarraga,et al.  Colloidal Microworms Propelling via a Cooperative Hydrodynamic Conveyor Belt. , 2015, Physical review letters.

[48]  Marco Dorigo,et al.  Revision History , 2003 .

[49]  G M Whitesides,et al.  Dynamic, self-assembled aggregates of magnetized, millimeter-sized objects rotating at the liquid-air interface: macroscopic, two-dimensional classical artificial atoms and molecules. , 2001, Physical review. E, Statistical, nonlinear, and soft matter physics.