Obstacle-aware navigation of smart microswimmers in a turbulent flow
Abstract
Microswimmers in turbulent flows often navigate complex, heterogeneous, and obstacle-rich environments, where they exhibit intricate behaviors such as trapping at and escape from obstacles. We generalize recent Q-learning methods of J.K. Alageshan et al. [Phys.Rev.E 101, 043110 (2020)] and A. Gupta et al. [Physics of Fluids 37, 045107 (2025)] developed for non-interacting microswimmers that aim to move optimally from an initial position to a target, to account for the additional complication of an obstacle in the flow. We begin by considering one circular obstacle in forced two-dimensional (2D) Navier-Stokes turbulence in which the energy spectrum displays a forward cascade. We employ the volume-penalization method to introduce this obstacle within our doubly periodic simulation domain. We augment our adversarial Q-learning Refs.~Alageshan2020,Akanksha2025 by suppressing the tendency of microswimmers to get trapped in stagnation points in the vicinity of the obstacle. We demonstrate that smart microswimmers (SS), which adopt our obstacle-aware adversarial Q-learning strategy, outperform both na\"ive swimmers (NS) and surfers (SuS).
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