Hydrodynamic Interaction and Geometric Memory Effect Drive Directed Swimming of Chlamydomonas reinhardtii near Periodic Microstructures
Abstract
The movement of microorganisms near solid-liquid interfaces is a topic of significant scientific interest due to its relevance in various natural and industrial contexts, such as biofilm formation and marine biofouling. In this study, we investigate the swimming behavior of C. reinhardtii near a sinusoidal periodic microstructure (SPM). Using fluorescence microscopy and three-dimensional tracking, we observe that the swimming direction of C. reinhardtii is strongly influenced by the geometric constraints of the SPM. Our results show that cells tend to aggregate at the bottom of the SPM rather than the top, and exhibit a speed orientation tendency near the microstructure. We attribute this behavior to a combination of the "memory effect" and hydrodynamic attraction. By altering the shape of the periodic microstructure, we successfully achieve directed induction of cell swimming, which has potential applications in micro-nano robot control and biofouling prevention. This work provides new insights into the movement mechanisms of microorganisms near solid-liquid surfaces and highlights the potential for manipulating their behavior through microstructure design.
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