Self-propulsion

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The sequence of images demonstrating the rotation of the self-propelled PVC tubing, containing camphor. The time separation between frames is 0.33 s. SelfPropulsion.jpg
The sequence of images demonstrating the rotation of the self-propelled PVC tubing, containing camphor. The time separation between frames is 0.33 s.

Self-propulsion is the autonomous displacement of nano-, micro- and macroscopic natural and artificial objects, containing their own means of motion. [2] [3] [4] [5] [6] [7] Self-propulsion is driven mainly by interfacial phenomena. [8] Various mechanisms of self-propelling have been introduced and investigated, which exploited phoretic effects, [9] gradient surfaces, breaking the wetting symmetry of a droplet on a surface, [10] [11] the Leidenfrost effect, [12] [13] [14] the self-generated hydrodynamic and chemical fields originating from the geometrical confinements, [15] and soluto- and thermo-capillary Marangoni flows. [16] [17] [1] Self-propelled system demonstrate a potential as micro-fluidics devices [18] and micro-mixers. [19] Self-propelled liquid marbles have been demonstrated. [14]

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Raymond Ethan Goldstein FRS FInstP is Schlumberger Professor of Complex Physical Systems in the Department of Applied Mathematics and Theoretical Physics (DAMTP) at the University of Cambridge and a Fellow of Churchill College, Cambridge.

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References

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