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Controlled Nitrogen Release by Hydroxyapatite Nanomaterials in Leaves Enhances Plant Growth and Nitrogen Uptake

Bhaskar Sharma, Hagay Kohay, Sandeep Sharma, Marina Youngblood, Jarad P. Cochran, Jason M. Unrine, Olga V. Tsyusko, Gregory V. Lowry, Juan Pablo Giraldo

2025ACS Nano26 citationsDOI

Abstract

Nitrogen fertilizer delivery inefficiencies limit crop productivity and contribute to environmental pollution. Herein, we developed Zn- and Fe-doped hydroxyapatite nanomaterials (ZnHAU, FeHAU) loaded with urea (∼26% N) through hydrogen bonding and metal–ligand interactions. The nanomaterials attach to the leaf epidermal cuticle and localize in the apoplast of leaf epidermal cells, triggering a slow N release at acidic conditions (pH 5.8) that promote wheat ( Triticum aestivum ) growth and increased N uptake compared to conventional urea fertilizers. ZnHAU and FeHAU exhibited prolonged N release compared to urea in model plant apoplast fluid pH in vitro (up to 2 days) and in leaf membranes in plants (up to 10 days) with a high N retention (32% to 53%) under simulated high rainfall events (50 mm). Foliar N delivery doses of up to 4% as ZnHAU and FeHAU did not induce toxicity in plant cells. The foliar-applied ZnHAU and FeHAU enhanced fresh and dry biomass by ∼214% and ∼161%, and N uptake by ∼108% compared to foliar-applied urea under low soil N conditions in greenhouse experiments. Controlled N release by leaf-attached nanomaterials improves N delivery and use efficiency in crop plants, creating nanofertilizers with reduced environmental impact.

Topics & Concepts

NitrogenNanomaterialsPlant growthMaterials scienceReactive nitrogen speciesNanotechnologyChemical engineeringChemistryBotanyReactive oxygen speciesBiologyBiochemistryOrganic chemistryEngineeringPolymer-Based Agricultural EnhancementsCarbon and Quantum Dots ApplicationsPlant Growth Enhancement Techniques