Hydroponic crop production in space is crucial for long-term space travel but faces numerous challenges – one of which is providing sufficient dissolved oxygen (DO) in a nutrient solution. In microgravity environments, surface tension is the primary force acting on liquids, causing water to form into suspended spherical droplets.
This can suffocate plants as the liquid clings onto plant roots and the lack of aeration deprives the plant of oxygen needed for growth. To overcome these challenges, plant water management (PWM) systems explore options of growing plants in space autonomously and passively through capillary forces. From 2018-2023, there have been 6 PWM experiments conducted on the ISS. In past experiments conducted in microgravity, bubbles formed in test cells have disrupted fluid dynamics and may adversely affect plant growth.
The accumulation of bubbles may lead to inconsistent nutrient delivery, break prime in tubing, and suspend plant roots in air, leading to plant stress and eventually death. Current research efforts focus on the oxygenation capabilities of the PWM system along with a comprehensive sensor array that will improve nutrient and DO monitoring capabilities.
Wang, Lillian & Massa, Gioia & Costine, Blake & Carlos, Danny & Spencer, Lashelle & Carro, R. & Torres, L. & Krischcko, O. & Jenson, R. & Dufour, N. & Hatch, T. & Mcquillen, J. & Dreschel, Thomas. (2024). Ground-based Characterization of Plant Water Management (PWM) Hydroponic Root Modules for Spaceflight. DOI: 10.13140/RG.2.2.17543.30887.
Source: Research Gate