Optimal chirality enhances long-range fluctuation-induced interactions in active fluids

Understanding how chiral active particles -- which self-propel and self-rotate -- interact with each other is crucial to uncover how chiral active matter self-organizes into dynamic structures and patterns. Long-range fluctuation-induced (FI) forces in nonequilibrium steady states of active matter systems can be considerably strong and govern structure formation in interplay with other interactions. However, the impact of chirality on FI forces is not understood to date. We study effective forces between intruders immersed in chiral active fluids with tunable chirality and find that the influence of chirality on the FI force nontrivially depends on the elongation of active particles. By increasing the ratio between self-rotation and self-propulsion, the FI force monotonically decreases for fully circular active objects, as the active bath structure gradually changes from rotating flocks and vortices to localized spinners. Contrarily, a nonmonotonic behavior is observed upon increasing the chirality of rodlike active objects: There exists an optimal chiral angle which maximizes the magnitude and range of the FI interaction. We obtain the phase diagram of transition between attractive and repulsive forces in the space of chirality, propulsion, and separation between intruders. By measuring the collision statistics between active particles and intruders at different chirality and separation, we establish a direct link between the FI force and the average collision number and demonstrate how the balance of collisions around the intruders varies with chirality and separation. Our results provide new insights into an interplay between activity, chirality, and self assembly.