Synergy of Phosphate-Controlled Release and Sulfur Oxidation in Novel Polysulfide Composites for Sustainable Fertilization

The development of smart and eco-friendly fertilizers is pivotal to guarantee food security sustainably. Phosphate rock and struvite are promising alternatives for P fertilization; nevertheless, the solubility of these sources is a challenge for consistent use efficiency. Here, we propose using a polysulfide obtained via inverse vulcanization as a novel controlled-release fertilizer matrix in a system containing either Baytivar rock (Bay) or struvite (Str). The polysulfide provides S for plants after being biologically oxidized to sulfate in soil, generating local acidity for P solubilization. After 15 days of soil incubation, the composites with 75 wt % Str and 75 wt % Bay achieved, respectively, 3 and 2 times the S oxidation from the elemental sulfur reference. Results indicated that P content stimulates the soil microorganisms' activity for S oxidation. The matrix had a physical role in improving Bay dissolution and regulating the rapid release from Str. Moreover, the available P in soil was 25-30 mg/dm(3) for Bay composites, while for pure Bay, it was 9 mg/dm(3).

Automated summary

The development of smart and eco-friendly fertilizers is crucial for sustainable food security. Phosphate rock and struvite are promising alternatives for phosphorus fertilization, but their solubility presents a challenge for consistent use efficiency. A novel controlled-release fertilizer matrix using a polysulfide obtained via inverse vulcanization shows potential in improving phosphorus solubilization and sulfur availability for plants in soil.