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Spherical catalytic micromotors fabricated as described in Wheat et al. [Langmuir 26, 13052 (2010)] show fuel concentration dependent translational and rotational velocity. The motors possess short-time and long-time diffusivities that scale with the translational and rotational velocity with respect to fuel concentration. The short-time diffusivities are two to three orders of magnitude larger than the diffusivity of a Brownian sphere of the same size, increase linearly with concentration, and scale as v(2)/2 omega. The measured long-time diffusivities are five times lower than the short-time diffusivities, scale as v(2)/{2D(r)[ 1 + (omega/D-r)(2)]}, and exhibit a maximum as a function of concentration. Maximums of effective diffusivity can be achieved when the rotational velocity has a higher order of dependence on the controlling parameter(s), for example fuel concentration, than the translational velocity. A maximum in diffusivity suggests that motors can be separated or concentrated using gradients in fuel concentration. The decrease of diffusivity with time suggests that motors will have a high collision probability in confined spaces and over short times; but will not disperse over relatively long distances and times. The combination of concentration dependent diffusive time scales and nonmonotonic diffusivity of circle-swimming motors suggests that we can expect complex particle responses in confined geometries and in spatially dependent fuel concentration gradients.
- Marine, Nathan (Author)
- Wheat, Philip (Author)
- Ault, Jesse (Author)
- Posner, Jonathan D. (Author)
- Ira A. Fulton Schools of Engineering (Contributor)
Marine, N. A., Wheat, P. M., Ault, J., & Posner, J. D. (2013). Diffusive behaviors of circle-swimming motors. Physical Review E, 87(5), 052305. doi:10.1103/PhysRevE.87.052305 "Copyright 2013 by the American Physical Society."
- 2013-08-12 04:48:09
- 2021-10-27 04:28:40
- 3 years ago