Improving Hydrodynamic Modeling of Free-Swimming Algae Using a Modified Three-Sphere Approach

TL;DR

This paper improves the minimal three-sphere model of algae swimming by incorporating refined flagellar dynamics and differential drag, leading to more accurate predictions of flow fields generated by microswimmers.

Contribution

The study introduces a modified three-sphere model with differential drag to better replicate experimentally observed flow fields of swimming algae.

Findings

Standard model fails to match experimental flow characteristics.

Refined flagellar beating dynamics improve flow field predictions.

Differential drag on flagellar spheres is crucial for accurate modeling.

Abstract

The beating flagella of the green alga Chlamydomonas reinhardtii play a prominent role in cellular mechanics, enabling cells to both displace and sense surrounding fluid. Specifically, flagellum-induced fluid transport enables microalgae to swim through fluid media and interact with other microorganisms. Minimal models, such as the three-sphere model with one sphere representing the cell body and two orbiting spheres mimicking the flagella, have been widely adopted to study various aspects of algal motility, including the synchronization of flagellar beating, run-and-tumble swimming, responses to shear flow, cell-body rolling, and helical navigation. However, detailed investigation of the algal flow fields generated by this minimal model remains limited. In this study, we systematically examine the time-averaged and time-resolved fluid flows generated by the three-sphere algae model and compare the numerical predictions with experimental data. Our findings reveal that the standard three-sphere model fails to produce key flow characteristics observed experimentally. To address this discrepancy, we explore a modified three-sphere model with refined flagellar beating dynamics and identify that differential drag acting on the flagellar spheres is the dominant factor influencing the fidelity of the modeled flow fields. These results advance the fundamental understanding of the flagellum-fluid interactions and algal flow and enhance our ability to accurately simulate microswimmer dynamics.