How can microfluidic-generated biodegradable capsules be engineered to selectively release multiple nutrients at different stages of plant growth while maintaining structural integrity? What are the physicochemical limitations of biodegradable polymers in extreme agricultural conditions (e.g., high salinity, arid climates), and how can they be optimized for long-term stability? How can AI-driven predictive modeling improve the precision of nutrient release in microfluidic fertilizer systems, and what are the computational challenges in simulating dynamic soil-plant interactions?
How can microfluidic-generated biodegradable capsules be engineered to selectively release multiple nutrients at different stages of plant growth while maintaining structural integrity?
What are the physicochemical limitations of biodegradable polymers in extreme agricultural conditions (e.g., high salinity, arid climates), and how can they be optimized for long-term stability?
How can AI-driven predictive modeling improve the precision of nutrient release in microfluidic fertilizer systems, and what are the computational challenges in simulating dynamic soil-plant interactions?