posted on 2022-08-02, 12:06authored byJianjie Li, Xiaoli He, Huaide Jiang, Yi Xing, Bi Fu, Chengzhi Hu
Advances in the versatile design and synthesis of nanomaterials
have imparted diverse functionalities to Janus micromotors as autonomous
vehicles. However, a significant challenge remains in maneuvering
Janus micromotors by following desired trajectories for on-demand
motility and intelligent control due to the inherent rotational Brownian
motion. Here, we present the enhanced and robust directional propulsion
of light-activated Fe3O4@TiO2/Pt
Janus micromotors by magnetic spinning and the Magnus effect. Once
exposed to a low-intensity rotating magnetic field, the micromotors
become physically actuated, and their rotational Brownian diffusion
is quenched by the magnetic rotation. Photocatalytic propulsion can
be triggered by unidirectional irradiation based on a self-electrophoretic
mechanism. Thus, a transverse Magnus force can be generated due to
the rotational motion and ballistic motion (photocatalytic propulsion)
of the micromotors. Both the self-electrophoretic propulsion and the
Magnus force are periodically changed due to the magnetic rotation,
which results in an overall directed motion moving toward a trajectory
with a deflection angle from the direction of incident light with
enhanced speed, maneuverability, and steering robustness. Our study
illustrates the admirable directional motion capabilities of light-driven
Janus micromotors based on magnetic spinning and the Magnus effect,
which unfolds a new paradigm for addressing the limitations of directionality
control in the current asymmetric micromotors.