Emergence Of Directional Rotation In Optothermally Activated Colloidal System

Abstract

We experimentally demonstrate the emergence of directional rotation in thermally active-passive colloidal structures under optical confinement. The observed handedness of rotation of the structure can be controlled by changing the relative position of the constituent colloids. We show that the angular velocity of rotation is sensitive to the intensity of the incident optical fields and the size of the constituent colloidal entities. The emergence of rotational dynamics can be understood in the context of asymmetric temperature distribution in the system and the relative location of the active colloid, which creates a local imbalance of optothermal torques to the confined system. Our work demonstrates how localized optothermal fields lead to directional rotational dynamics without explicitly utilizing spin or orbital angular momentum of light. We envisage that our results will have implications in realizing Brownian engines, and can directly relate to rotational dynamics in biological and ecological systems.