The [LC]² research programme is divided into three work packages, each of which has produced notable results. The first (WP1) concerned developing novel approaches to modelling active fluids. It successfully developed, implemented and quantified a coarse-grained algorithm for simulating spontaneously flowing active fluids, which is ideal for embedding colloids within. Furthermore, the project advanced methods for simulating active systems, including motile bacteria, epithelial tissues and layered liquid crystals. By advancing the ability of researchers to model different types of active materials, WP1 increased our capacity to design animate materials. These models have been employed to simulate how active fluids flow when confined in microfluidic geometries.
While WP1 advanced the ‘living’ aspect of [LC]², work package two (WP2) tackled the ‘colloidal’ facet of ‘Living’ Colloidal Liquid Crystals. WP2 developed an algorithm for simulating passive composite colloidal/liquid crystal materials. These include small particles, called colloids, embedded in nematic-type liquid crystals, which are fluids composed of aligned, rod-like molecules. The [LC]² team quantified the interactions between different colloids and how they entangle within the nematic liquid crystal. Flexible polymers chains in nematics were studied to discover how their sudden turns can untangle in time. The hybrid approach represents a methodological advance for studying composite material systems across length scales.
These ideas were brought together in work package three (WP3). The [LC]² team built simulations to model rotating 2D colloids above an active fluid and compared this directly to experiments, and designed particles with different north and south hemispheres, called Janus particles. Janus can steal surrounding activity to propel themselves, thus becoming self-propelled particles. The [LC]² team studied how the activity-driven dynamics of rods differs from spherical particles, the dynamics of flexible polymers in active turbulence and discovered an active version of Darcy's Law for flow through porous environments.
Thus, foundational work has been accomplished, results obtained and discoveries disseminated as a result of [LC]². The groundwork for achieving ‘living’ colloidal liquid crystals has been laid by developing codes for active nematics and colloidal liquid crystals, which have been quantified and merged into a single simulation package. The work resulted in 24 peer-reviewed articles, over 100 conferences, workshops and colloquia presentations and 18 collaborations, including with 7 experimentalists.