Trochoidal trajectories of self-propelled Janus particles in a diverging laser beam
We describe colloidal Janus particles with metallic and dielectric faces that swim vigorously
when illuminated by defocused optical tweezers without consuming any chemical fuel.
Rather than wandering randomly, these optically-activated colloidal swimmers circulate
back and forth through the beam of light, tracing out sinuous rosette patterns. We propose a
model for this mode of light-activated transport that accounts for the observed behavior
through a combination of self-thermophoresis and optically-induced torque. In the …
when illuminated by defocused optical tweezers without consuming any chemical fuel.
Rather than wandering randomly, these optically-activated colloidal swimmers circulate
back and forth through the beam of light, tracing out sinuous rosette patterns. We propose a
model for this mode of light-activated transport that accounts for the observed behavior
through a combination of self-thermophoresis and optically-induced torque. In the …
We describe colloidal Janus particles with metallic and dielectric faces that swim vigorously when illuminated by defocused optical tweezers without consuming any chemical fuel. Rather than wandering randomly, these optically-activated colloidal swimmers circulate back and forth through the beam of light, tracing out sinuous rosette patterns. We propose a model for this mode of light-activated transport that accounts for the observed behavior through a combination of self-thermophoresis and optically-induced torque. In the deterministic limit, this model yields trajectories that resemble rosette curves known as hypotrochoids.
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