Magnetic propulsion of colloidal microrollers controlled by electrically modulated friction.

Precise control over the motion of magnetically responsive particles in fluidic chambers is important for probing and manipulating tasks in prospective microrobotic and bio-analytical platforms. We have previously exploited such colloids as shuttles for the microscale manipulation of objects. Here, we study the rolling motion of magnetically driven Janus colloids on solid substrates under the influence of an orthogonal external electric field. Electrically induced attractive interactions were used to tune the load on the Janus colloid and thereby the friction with the underlying substrate, leading to control over the forward velocity of the particle. Our experimental data suggest that the frictional coupling required to achieve translation, transitions from a hydrodynamic regime to one of mixed contact coupling with increasing load force. Based on this insight, we show that our colloidal microrobots can probe the local friction coefficient of various solid surfaces, which makes them potentially useful as tribological microsensors. Lastly, we precisely manipulate porous cargos using our colloidal rollers, a feat that holds promise for bio-analytical applications.

[1]  Metin Sitti,et al.  Multifunctional surface microrollers for targeted cargo delivery in physiological blood flow , 2020, Science Robotics.

[2]  Tao Yang,et al.  Microwheels on microroads: Enhanced translation on topographic surfaces , 2019, Science Robotics.

[3]  Metin Sitti,et al.  Shape-encoded dynamic assembly of mobile micromachines , 2019, Nature Materials.

[4]  S. N. Bhatia,et al.  Synthetic and living micropropellers for convection-enhanced nanoparticle transport , 2019, Science Advances.

[5]  W. Poon,et al.  Testing the Wyart-Cates model for non-Brownian shear thickening using bidisperse suspensions. , 2019, Soft matter.

[6]  André R Studart,et al.  Active cargo transport with Janus colloidal shuttles using electric and magnetic fields. , 2018, Soft matter.

[7]  D. Wiersma,et al.  Light Robots: Bridging the Gap between Microrobotics and Photomechanics in Soft Materials , 2018, Advanced materials.

[8]  Metin Sitti,et al.  Small-scale soft-bodied robot with multimodal locomotion , 2018, Nature.

[9]  N. Spencer,et al.  Roughness-dependent tribology effects on discontinuous shear thickening , 2018, Proceedings of the National Academy of Sciences.

[10]  C. Wirth,et al.  Motion of a Janus particle very near a wall. , 2017, The Journal of chemical physics.

[11]  M. Loessner,et al.  Colloidal shuttles for programmable cargo transport , 2017, Nature Communications.

[12]  Ying-Wei Yang,et al.  Metal–Organic Framework (MOF)‐Based Drug/Cargo Delivery and Cancer Therapy , 2017, Advanced materials.

[13]  Jan Becker Høgsberg,et al.  Aalborg Universitet Characterization of clay-modified thermoset polymers under various environmental conditions for the use in high-voltage power pylons , 2017 .

[14]  Helena Massana-Cid,et al.  Assembly and Transport of Microscopic Cargos via Reconfigurable Photoactivated Magnetic Microdockers. , 2017, Small.

[15]  T. Palberg,et al.  Assembly and Speed in Ion-Exchange-Based Modular Phoretic Microswimmers. , 2017, Langmuir : the ACS journal of surfaces and colloids.

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

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

[18]  T Patino,et al.  Miniaturized soft bio-hybrid robotics: a step forward into healthcare applications. , 2016, Lab on a chip.

[19]  Alicia M. Boymelgreen,et al.  Propulsion of Active Colloids by Self-Induced Field Gradients. , 2016, Langmuir : the ACS journal of surfaces and colloids.

[20]  Salvador Pané,et al.  Soft micromachines with programmable motility and morphology , 2016, Nature Communications.

[21]  Jie Zhang,et al.  Directed Self-Assembly Pathways of Active Colloidal Clusters. , 2016, Angewandte Chemie.

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

[23]  I. Cohen,et al.  Hydrodynamic and Contact Contributions to Continuous Shear Thickening in Colloidal Suspensions. , 2015, Physical review letters.

[24]  T. Huang,et al.  Selectively manipulable acoustic-powered microswimmers , 2015, Scientific Reports.

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

[26]  Ying Wang,et al.  Mesoporous silica nanoparticles in drug delivery and biomedical applications. , 2015, Nanomedicine : nanotechnology, biology, and medicine.

[27]  T. Coopmans,et al.  Orientation of a dielectric rod near a planar electrode. , 2014, Physical chemistry chemical physics : PCCP.

[28]  Jake J. Abbott,et al.  Behavior of rotating magnetic microrobots above the step-out frequency with application to control of multi-microrobot systems , 2014 .

[29]  Samuel Sanchez,et al.  Self-Propelled Micromotors for Cleaning Polluted Water , 2013, ACS nano.

[30]  Steve Granick,et al.  Colloidal ribbons and rings from Janus magnetic rods , 2013, Nature Communications.

[31]  S. Granick,et al.  Electric field-induced assembly of monodisperse polyhedral metal-organic framework crystals. , 2013, Journal of the American Chemical Society.

[32]  Roy Clarke,et al.  Magnetically uniform and tunable Janus particles , 2011 .

[33]  Seung‐Man Yang,et al.  Magnetoresponsive microparticles with nanoscopic surface structures for remote-controlled locomotion. , 2010, Angewandte Chemie.

[34]  Lixin Dong,et al.  Artificial bacterial flagella: Fabrication and magnetic control , 2009 .

[35]  Ignacio Pagonabarraga,et al.  Controlled swimming in confined fluids of magnetically actuated colloidal rotors. , 2008, Physical review letters.

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

[37]  U. Michigan,et al.  Slipping friction of an optically and magnetically manipulated microsphere rolling at a glass-water interface , 2008, 0803.0328.

[38]  Rhodri H. Armour,et al.  Rolling in nature and robotics: A review , 2006 .

[39]  Tony S. Yu,et al.  Experimental Investigations of Elastic Tail Propulsion At Low Reynolds Number , 2006, cond-mat/0606527.

[40]  D. Grier,et al.  Colloidal electrostatic interactions near a conducting surface. , 2006, Physical review. E, Statistical, nonlinear, and soft matter physics.

[41]  M. Ozols,et al.  Dynamics of an active magnetic particle in a rotating magnetic field. , 2006, Physical review. E, Statistical, nonlinear, and soft matter physics.

[42]  John E. Sader,et al.  Normal and torsional spring constants of atomic force microscope cantilevers , 2004 .

[43]  D. Grier,et al.  The charge of glass and silica surfaces , 2001, cond-mat/0105149.

[44]  J. Bechhoefer,et al.  Calibration of atomic‐force microscope tips , 1993 .

[45]  F. Wilczek,et al.  Geometry of self-propulsion at low Reynolds number , 1989, Journal of Fluid Mechanics.

[46]  K. Stout Fluid film lubrication , 1982 .

[47]  R. G. Cox,et al.  Slow viscous motion of a sphere parallel to a plane wall—I Motion through a quiescent fluid , 1967 .

[48]  Sirilak Sattayasamitsathit,et al.  Self-propelled activated carbon Janus micromotors for efficient water purification. , 2015, Small.

[49]  K. Ley,et al.  Biomechanics of leukocyte rolling. , 2011, Biorheology.

[50]  C. Dong,et al.  Biomechanics of cell rolling: shear flow, cell-surface adhesion, and cell deformability. , 2000, Journal of biomechanics.

[51]  H. Butt,et al.  Calculation of thermal noise in atomic force microscopy , 1995 .

[52]  S. Bike,et al.  Measuring double layer repulsion using total internal reflection microscopy , 1993 .