Biological systems Most animals can be seen as SPP: they find energy in their food and exhibit various locomotion strategies, from flying to crawling. The most prominent examples of collective behaviours in these systems are fish schools, birds flocks, sheep herds, human crowds. At a smaller scale, cells and bacteria can also be treated as SPP. These biological systems can propel themselves based on the presence of chemoattractants. At even smaller scale,
molecular motors transform ATP energy into directional motion. Recent work has shown that enzyme molecules will also propel themselves. Further, it has been shown that they will preferentially move towards a region of higher substrate concentration, a phenomenon that has been developed into a purification technique to isolate live enzymes. Additionally, microparticles, vesicles, and even macroscale sheets can become self-propelled when they are functionalized with enzymes. The catalytic reactions of the enzymes direct the particles or vesicles based on corresponding substrate gradients.
Artificial systems in hydrogen peroxide due to self-electrophoretic forces. There is a distinction between wet and dry systems. In the first case the particles "swim" in a surrounding fluid; in the second case the particles "walk" on a substrate. Active colloidal particles, dubbed
nanomotors, are the prototypical example of wet SPP.
Janus particles are colloidal particles with two different sides, having different physical or chemical properties. This
symmetry breaking allows, by properly tuning the environment (typically the surrounding solution), for the motion of the Janus particle. For instance, the two sides of the Janus particle can induce a local gradient of, temperature, electric field, or concentration of chemical species. This induces motion of the Janus particle along the gradient through, respectively,
thermophoresis,
electrophoresis or
diffusiophoresis. In a solution of hydrogen peroxide, this "nanomotor" would exhibit a catalytic oxidation-reduction reaction, thereby inducing a fluid flow along the surface through self-diffusiophoresis. A similar system used a copper-platinum rod in a bromine solution. A recent study demonstrated the control of the positions and orientations of these active nanorods under confined microfluidic nozzles using ultrasound. • Another Janus SPP was developed by coating half of a polystyrene bead with platinum. It was also found that metal–organic framework (MOF)-based Janus micromotors can function as light-powered active colloids, capable of autonomous propulsion and enabling real-time surface-enhanced Raman sensing in chemically complex environments. • Another example of a Janus SPP is an organometallic motor using a gold-silica microsphere.
Grubb's catalyst was tethered to the silica half of the particle and in solution of monomer would drive a catalytic polymerization. The resulting concentration gradient across the surface would propel the motor in solution. • Another example of an artificial SPP are platinum spinner microparticles that have controllable rotations based on their shape and symmetry. By utilizing multidirectional magnetic fields, the trajectories of these particles can also be directed into specific patterns. • Another example is biphasic Janus oil droplets which shows self propelled motion. • Several other examples are described in the
nanomotor-specific page. Walking grains are a typical realization of dry SPP: The grains are milli-metric disks sitting on a vertically vibrating plate, which serves as the source of energy and momentum. The disks have two different contacts ("feet") with the plate, a hard needle-like foot in the front and a large soft rubber foot in the back. When shaken, the disks move in a preferential direction defined by the polar (head-tail) symmetry of the contacts. This together with the vibrational noise result in a persistent random walk. == Symmetry breaking ==