Advanced Vermicomposting Modality: Microbial Acceleration to Improve Micronutrient Profile of Agricultural Residue Derived Compost

Advancing circular economies and self-reliant agricultural systems will critically depend on innovative strategies to optimize resource utilization and agro-waste recycling for the sustainability of food production. The present study is focused on the potential of vermitechnology with diverse substrate compositions in bioconverting lignocellulosic agricultural residues into nutrient-rich amendments. Trials of vermicomposting were carried out exploiting Eudrilus eugeniae and a fungal decomposer consortium, Pusa Decomposer. Treatments included T1: Gliricidia sepium leaves (GL), T2: Banana pseudostem (BP), T3: Rice straw (RS), T4: Rice husk (RH), T5 (RS + BP – 8:1 w/w), T6 (RH + BP - 8:1 w/w), T7 (RH + RS + BP – 4:4:1 w/w) and T8 (RH + RS + BP + GL – 4:4:0.5:0.5 w/w) with 3 replications in CRD. T2 expressed peak Mn, Zn and Cu values at 418.40 mg kg-1, 247.50 mg kg-1 and 55.12 mg kg-1, respectively. T3 reported summit Fe and B at 8669.50 mg kg-1 and 37.00 mg kg-1, respectively. It was found that the combination of RS and BP reported excellent nutrient solubilization and enhanced EC, which ratiocinates the role of substrate mix in determining vermicompost quality. These findings emphasize the importance of substrate selection and microbial augmentation with fungal decomposer consortia such as Pusa decomposer, which optimize the vermicomposting process for nutrient recovery and improved soil health.