Shape-directed rotation of homogeneous micromotors via catalytic self-electrophoresis

The pursuit of chemically-powered colloidal machines requires individual components that perform different motions within a common environment. Such motions can be tailored by controlling the shape and/or composition of catalytic microparticles; however, the ability to design particle motions remains limited by incomplete understanding of the relevant propulsion mechanism(s). Here, we demonstrate that platinum microparticles move spontaneously in solutions of hydrogen peroxide and that their motions can be rationally designed by controlling particle shape. Nanofabricated particles with n-fold rotational symmetry rotate steadily with speed and direction specified by the type and extent of shape asymmetry. The observed relationships between particle shape and motion provide evidence for a self-electrophoretic propulsion mechanism, whereby anodic oxidation and cathodic reduction occur at different rates at different locations on the particle surface. We develop a mathematical model that explains how particle shape impacts the relevant electrocatalytic reactions and the resulting electrokinetic flows that drive particle motion.Self-propelled motors operating at the micro- or nanoscale can be powered by catalytic reactions and show appealing potential in robotic applications. Brooks et al. describe how the motions of platinum spinners in hydrogen peroxide solutions can be rationally designed by controlling particle shape.

[1]  P. Debye,et al.  Reaction Rates in Ionic Solutions , 1942 .

[2]  W. Wynne-Jones,et al.  The behaviour of mixtures of hydrogen peroxide and water. Part 1.—Determination of the densities of mixtures of hydrogen peroxide and water , 1952 .

[3]  H. Gerischer,et al.  Über die katalytische Zersetzung von Wasserstoffsuperoxyd an metallischem Platin. , 1956 .

[4]  R. Bowen,et al.  Behaviour of the oxygen-peroxide couple on platinum☆ , 1969 .

[5]  F. Stillinger Proton Transfer Reactions and Kinetics in Water , 1978 .

[6]  Lee R. White,et al.  Electrophoretic mobility of a spherical colloidal particle , 1978 .

[7]  L. White,et al.  Dielectric response and conductivity of dilute suspensions of colloidal particles , 1981 .

[8]  John L. Anderson,et al.  Colloid Transport by Interfacial Forces , 1989 .

[9]  L. Janssen,et al.  Diffusion coefficients of oxygen, hydrogen peroxide and glucose in a hydrogel , 1993 .

[10]  Yanyan Cao,et al.  Catalytic nanomotors: autonomous movement of striped nanorods. , 2004, Journal of the American Chemical Society.

[11]  Shyamala Subramanian,et al.  Directed rotational motion of microscale objects using interfacial tension gradients continually generated via catalytic reactions. , 2005, Small.

[12]  Yang Wang,et al.  Catalytically induced electrokinetics for motors and micropumps. , 2006, Journal of the American Chemical Society.

[13]  T. Mallouk,et al.  Bipolar electrochemical mechanism for the propulsion of catalytic nanomotors in hydrogen peroxide solutions. , 2006, Langmuir : the ACS journal of surfaces and colloids.

[14]  Chad A Mirkin,et al.  Rational design and synthesis of catalytically driven nanorotors. , 2007, Journal of the American Chemical Society.

[15]  R. Golestanian,et al.  Designing phoretic micro- and nano-swimmers , 2007, cond-mat/0701168.

[16]  Ramin Golestanian,et al.  Self-motile colloidal particles: from directed propulsion to random walk. , 2007, Physical review letters.

[17]  John G. Gibbs,et al.  Autonomously motile catalytic nanomotors by bubble propulsion , 2009 .

[18]  O. Schmidt,et al.  Catalytic microtubular jet engines self-propelled by accumulated gas bubbles. , 2009, Small.

[19]  Raymond Kapral,et al.  Catalytic nanomotors: self-propelled sphere dimers. , 2010, Small.

[20]  J. Posner,et al.  Electrokinetic locomotion due to reaction-induced charge auto-electrophoresis , 2010, Journal of Fluid Mechanics.

[21]  D. Saintillan,et al.  Geometrically designing the kinematic behavior of catalytic nanomotors. , 2011, Nano letters.

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

[23]  Jonathan D. Posner,et al.  Role of Solution Conductivity in Reaction Induced Charge Auto-Electrophoresis , 2012, 1309.1474.

[24]  W. Xi,et al.  Self-propelled nanotools. , 2012, ACS nano.

[25]  T. Mallouk,et al.  Understanding the efficiency of autonomous nano- and microscale motors. , 2013, Journal of the American Chemical Society.

[26]  Wilson Poon,et al.  Ionic effects in self-propelled Pt-coated Janus swimmers. , 2013, Soft matter.

[27]  Samuel Sanchez,et al.  Stimuli-Responsive Microjets with Reconfigurable Shape , 2014, Angewandte Chemie.

[28]  Sharon C Glotzer,et al.  Emergent collective phenomena in a mixture of hard shapes through active rotation. , 2013, Physical review letters.

[29]  John G. Gibbs,et al.  Nanopropellers and their actuation in complex viscoelastic media. , 2014, ACS nano.

[30]  Gary J. Dunderdale,et al.  Electrokinetic effects in catalytic platinum-insulator Janus swimmers , 2013, 1312.6250.

[31]  Ke Chen,et al.  Catalytic microrotor driven by geometrical asymmetry. , 2015, The Journal of chemical physics.

[32]  Michele Dipalo,et al.  Micromotors with asymmetric shape that efficiently convert light into work by thermocapillary effects , 2015, Nature Communications.

[33]  E. Lauga,et al.  Autophoretic locomotion from geometric asymmetry , 2015, The European physical journal. E, Soft matter.

[34]  S. Glotzer,et al.  Coarsening dynamics of binary liquids with active rotation. , 2015, Soft matter.

[35]  Ramin Golestanian,et al.  Self-assembly of active colloidal molecules with dynamic function. , 2015, Physical review. E, Statistical, nonlinear, and soft matter physics.

[36]  Enkeleida Lushi,et al.  Collective dynamics in a binary mixture of hydrodynamically coupled microrotors. , 2015, Physical review letters.

[37]  Samuel Sánchez,et al.  Chemically powered micro- and nanomotors. , 2015, Angewandte Chemie.

[38]  Sharon C Glotzer,et al.  Shape control and compartmentalization in active colloidal cells , 2015, Proceedings of the National Academy of Sciences.

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

[40]  R. Bowley,et al.  Propulsion of a Two-Sphere Swimmer. , 2015, Physical review letters.

[41]  Joseph Wang,et al.  Rocket Science at the Nanoscale. , 2016, ACS nano.

[42]  G. Volpe,et al.  Active Particles in Complex and Crowded Environments , 2016, 1602.00081.

[43]  Wei Wang,et al.  Density and Shape Effects in the Acoustic Propulsion of Bimetallic Nanorod Motors. , 2016, ACS nano.

[44]  Christian Holm,et al.  Ionic screening and dissociation are crucial for understanding chemical self-propulsion in polar solvents. , 2017, Soft matter.

[45]  J. Posner,et al.  Phoretic Self-Propulsion , 2017 .

[46]  R. Golestanian,et al.  'Fuelled' motion: phoretic motility and collective behaviour of active colloids. , 2017, Chemical Society reviews.

[47]  O. Velev,et al.  Engineering of Self‐Propelling Microbots and Microdevices Powered by Magnetic and Electric Fields , 2018 .

[48]  J. Rimstidt,et al.  Mechanism and Kinetics of Hydrogen Peroxide Decomposition on Platinum Nanocatalysts. , 2018, ACS applied materials & interfaces.

[49]  T. Mallouk,et al.  Shape-Directed Microspinners Powered by Ultrasound. , 2018, ACS nano.

[50]  David Reguera,et al.  Unraveling the Operational Mechanisms of Chemically Propelled Motors with Micropumps. , 2018, Accounts of chemical research.

[51]  Stefano Sacanna,et al.  Targeted assembly and synchronization of self-spinning microgears , 2018, Nature Physics.

[52]  Boyce E. Griffith,et al.  Transition in motility mechanism due to inertia in a model self-propelled two-sphere swimmer , 2018 .

[53]  K. Bishop,et al.  Shape-directed dynamics of active colloids powered by induced-charge electrophoresis , 2018, Proceedings of the National Academy of Sciences.

[54]  O. Velev,et al.  Supercolloidal Spinners: Complex Active Particles for Electrically Powered and Switchable Rotation , 2018, Advanced Functional Materials.

[55]  E. Lauga,et al.  Physics of Bubble‐Propelled Microrockets , 2018, 1803.10523.

[56]  Christian Scholz,et al.  Rotating robots move collectively and self-organize , 2018, Nature Communications.

[57]  P. Fischer,et al.  Bioinspired microrobots , 2018, Nature Reviews Materials.