000895477 001__ 895477
000895477 005__ 20240925204956.0
000895477 0247_ $$aG:(GEPRIS)237143019$$d237143019
000895477 035__ $$aG:(GEPRIS)237143019
000895477 040__ $$aGEPRIS$$chttp://gepris.its.kfa-juelich.de
000895477 150__ $$aSPP 1726: Mikroschwimmer - Von Einzelpartikelbewegung zu kollektivem Verhalten$$y2014 - 2024
000895477 371__ $$aProfessor Dr. Gerhard Gompper
000895477 450__ $$aDFG project G:(GEPRIS)237143019$$wd$$y2014 - 2024
000895477 5101_ $$0I:(DE-588b)2007744-0$$aDeutsche Forschungsgemeinschaft$$bDFG
000895477 680__ $$aLocomotion and transport of microorganisms in fluids is an essential aspect of life. Search for food, orientation toward light, spreading of progeny, and the formation of colonies require locomotion. Microorganisms, such as bacteria, algae and sperm, exploit flagella for propulsion. Swimming at the microscale occurs at low Reynolds numbers, where fluid friction and viscosity dominates inertia. This requires swimming strategies different from those of the macroscopic world. During evolution propulsion mechanisms developed that overcome or even exploit drag. Understanding these propulsion mechanisms opens an avenue for the control of biological systems and the design of artificial nanomachines, with a major impact on various research areas ranging from life science and material science to environmental science. For artificial microswimmers, alternative concepts to convert chemical energy or heat into directed motion can be employed, which are potentially more efficient.The dynamics of microswimmers shows many facets, which are all required to achieve locomotion. At the level of an individual swimmer, the propulsion mechanism needs to be unraveled. Thereby, the question on the energy supplied for persistent motion has to be addressed. The response to external stimuli by chemical signals, light, gravitational fields, and flow fields, represents another important area. A major challenge is the understanding and control of emergent collective behaviour of microswimmers. Here, the mechanisms underlying the formation of large-scale patterns, such as networks and swarms of microswimmer, needs to be addressed.The aim of the Priority Programme is to coherently combine the research activities on microswimmers in biology, biophysics, theoretical and experimental soft matter physics, and simulation sciences. Advanced experimental techniques, new nanotechnological tools, soft-matter chemistry and physics, and novel simulation approaches, promise deeper insights into the underlying physical and biochemical processes, and provide the tools to design and construct new artificial microswimmers. Accordingly, the major focus of the Priority Programme is:- understanding of biological microswimmers,- design and understanding of artificial microswimmers,- cooperative behaviour and swarming of ensembles of microswimmers.Several related systems exist, in which similar mechanisms are essential and similar types of structures are involved. On the mesoscale, these are mixtures of biological filaments and motor proteins, and vibrated granular systems; on the macroscale, swarms of birds and schools of fish emerge. Because the focus of the Priority Programme is on physical interactions between active particles, like excluded-volume and hydrodynamic interactions, we envisage beneficial synergies between related mesoscale systems. However, macroscale biological swarms are governed by other mechanisms, and are therefore outside of the focus of this Priority Programme.
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