Overview of Activities
The project focused on developing theoretical, computational, and experimental approaches to understand and control the collective behavior of biological and model microswimmers in confined environments. The activities were organized around the progressive construction of realistic models of active agents, the implementation of complex confinement geometries, and the comparison of numerical predictions with microfluidic experiments. Particular emphasis was placed on identifying mechanisms that emerge only from the interplay between activity, confinement, and external fields, and on translating these mechanisms into design principles for microscale transport and separation.
Development of Models for Active Agents
A significant activity of the project was the development and improvement of computational models for active agents, including and excluding hydrodynamic interactions depending on the physical question under investigation. Hydrodynamic squirmers were implemented within the Dissipative Particle Dynamics (DPD) framework in LAMMPS, enabling simulations of large suspensions under gravity with complete momentum conservation. In parallel, simplified active particle models, such as run-and-tumble and active Brownian particles without hydrodynamics, were employed to isolate the role of confinement and activity from fluid-mediated effects. This dual modeling strategy allowed systematic disentanglement of the physical mechanisms governing collective behavior.
Modeling of Confinement and External Fields
The project developed flexible numerical implementations of confined environments, including flat walls, asymmetric boundaries, funnel-like obstacles, and microchannel geometries inspired by microfluidic devices. These environments were combined with external fields such as gravity to study sedimentation, accumulation, and transport phenomena. The resulting simulation framework enabled the exploration of realistic scenarios in which microswimmers experience simultaneous confinement, external forcing, and interactions with other active or passive agents.
Gravity-Induced Structuring of Microswimmers
One of the main scientific achievements of the project was the systematic study of squirmer suspensions under gravity. This work culminated in the publication "Sedimentation and structure of squirmer suspensions under gravity" (Soft Matter, 2025). The simulations reproduced known results obtained with alternative numerical techniques, validating the DPD-based squirmer implementation. Beyond validation, the study revealed that the sedimented bottom monolayer transitions to an ordered phase with hexagonal symmetry as the gravitational strength increases. Importantly, the degree of hexagonal order was found to depend on swimmer type, being more robust in pullers than in pushers. These findings provide new insight into gravity and hydrodynamics-driven self-organization in active suspensions and suggest potential routes toward activity-based self-healing or self-organized surfaces.
Conceptual Design of a Separation Microsystem
Another key activity addressed the conceptual design of a microscale separation system exploiting the combined effects of activity and confinement. In "Sorting of binary active–passive mixtures in designed microchannels" (Soft Matter, 2025), mixtures of active and passive particles confined within microchannels with funnel-like obstacles were investigated. The obstacles acted as semipermeable barriers, selectively allowing passive particles to pass through narrow gaps. By tuning the tumbling rate of the active particles and the tilt angle of the obstacles, the system exhibited an optimal regime characterized by maximum separation efficiency and minimal response time. The underlying mechanism was identified as an activity-induced advective drift exerted by active particles on passive particles, leading to effective pumping of passive matter across the channel. This phenomenon, termed active pumping, constitutes a novel and general design principle for microscale separation and transport devices that harness microorganism motility rather than external actuation.
Discovery of Confinement-Induced Collective Motion
A particularly significant and unexpected outcome of the project was the discovery of a new type of collective motion purely induced by confinement. In a study currently under review ("Confinement-induced collective motion in suspensions of run-and-tumble particles", Journal of Chemical Physics), active suspensions were confined in microchannels with asymmetric boundaries: a flat upper wall and a lower wall patterned with funnel-like obstacles that block particle passage. Remarkably, dense traveling bands emerged whose formation and sustained motion required neither explicit alignment interactions, nor shape-induced alignment, nor hydrodynamic interactions, nor the presence of passive particles. The traveling structure was discovered serendipitously during the analysis of simulations originally performed for the separation study. Its propulsion mechanism resembles tracked locomotion observed in heavy vehicles, leading to the designation confinement-induced tracked locomotion. This finding demonstrates that confinement alone can generate coherent, directional collective motion in active matter, opening new perspectives for one-dimensional transport of microscopic objects. The phenomenon is expected to be experimentally realizable using suspensions of Chlamydomonas reinhardtii confined in appropriately designed microfluidic chambers.
Microfluidic Experiments with Microalgae–Colloid Mixtures
Complementing the theoretical and computational work, the project advanced experimental protocols for microfluidic studies of confined mixtures of phototactic microalgae ("Chlamydomonas reinhardtii") and passive colloids. Existing experimental setups were refined to achieve stable confinement, controlled illumination, and reproducible measurements of particle transport. Preliminary results, currently being finalized for publication ("Transport enhancement of colloidal particles in confined microalgal active baths"), demonstrate a significant enhancement of colloidal transport induced by the active bath under confinement. These experiments provide critical validation of simulation predictions and establish a direct link between model active systems and real biological microswimmers.
Summary of Outcomes
Overall, the project delivered a coherent set of models, simulations, and experiments that significantly advance the understanding of active matter under confinement. The outcomes include validated hydrodynamic models, novel confinement-induced ordering and transport mechanisms, and experimentally accessible design principles for microscale separation and delivery systems. Together, these results form a scientific foundation for future developments in active-matter-based technologies.