Dupont, B.; Benoit-Gonin, X.; Vincent-Bonnieu, S.; Aider, J.-L.; Ardre, M.

Space missions necessitate sustainable life support systems capable of producing oxygen and biomass under microgravity conditions. This study examines the use of acoustic levitation to trap and manipulate the filamentous cyanobacterium Limnospira indica PCC 8005 during parabolic flight experiments. We demonstrate that this helicoidal microorganism can be rapidly assembled into thin layers with a standing ultrasonic wave within a millimeter-scale fluidic chamber. Our findings indicate that significantly lower acoustic power is required under microgravity (0.79 mW) compared to terrestrial conditions (1.48 mW) to achieve stable trapping, suggesting energy-efficient bioprocessing in weightless environments. Monte Carlo simulations and light attenuation modelling reveal that structuring cyanobacteria into layered formations enhances light penetration, potentially overcoming the \"compensation point\" limitation observed in bulk cultures. These results pave the way for advanced photobioreactors that use acoustic manipulation, which improves photosynthetic efficiency and reduces energy consumption for oxygen generation and biomass production in space.